Radiographic imaging system

ABSTRACT

A radiographic imaging system includes an irradiating apparatus, a first clock, a radiographic imaging apparatus, a second clock and a hardware processor. The irradiating apparatus generates radiation. The first clock keeps time and works with the irradiating apparatus. The radiographic imaging apparatus generates image data based on received radiation. The second clock keeps time and works with the radiographic imaging apparatus. The hardware processor (i) obtains a clock value of the first clock at a predetermined time point and a clock value of the second clock at the predetermined time point respectively as first clock information and second clock information, (ii) makes a determination as to whether a specific condition is met based on the obtained first clock information and the obtained second clock information, and (iii) in response to the specific condition being met, performs a specific output.

CROSS REFERENCE TO PRIOR APPLICATIONS

The present application is a continuation application of U.S. patentapplication Ser. No. 16/360,501, filed on Mar. 21, 2019, the entirecontents of which is incorporated herein by reference and priority towhich is hereby claimed. Application Ser. No. 16/360,501 hereby claimspriority from Japanese Application No. 2018-056477, filed Mar. 23, 2018and Japanese Application No. 2018-056482, filed on Mar. 23, 2018, thedisclosures of which are both also incorporated herein by reference.

BACKGROUND 1. Technological Field

The present invention relates to a radiographic imaging system.

2. Description of the Related Art

Radiographic images have been taken with a radiographic imaging systemthat includes an irradiating apparatus for generating radiation and aradiographic imaging apparatus for generating image data of aradiographic image based on received radiation. In order to prevent theimaging apparatus from being irradiated over the charge accumulationtime of the imaging apparatus, techniques to ensure the operation of thesystem have been used that involve sending and receiving an irradiationpermission request signal and an irradiation permission signal betweenthe irradiating apparatus and the imaging apparatus (see JP2006-333898A, JP 2011-041866A, JP 2013-046819A and JP 2014-166578A).

In recent years, a dynamic behavior (movement) of a subject has beenanalyzed for diagnostic purposes by means of serial imaging in which thesubject is radiographed at regular intervals to take frame images.

In a serial imaging process, an imaging apparatus repeats an imagingsequence at predetermined intervals, which mainly involves accumulatingcharges caused by irradiation in imaging elements, reading andtransferring the accumulated charges and initializing the imagingelements.

Further, in a serial imaging process, the imaging sequence has to berepeated at a frame rate of as high as 15 frame/s or 30 frame/s so thatthe movement of a subject is completely captured. For example, even whena serial imaging process is performed at a relatively low frame rate of15 frame/s, each imaging sequence for taking a frame image has to becompleted within 66.6 ms. However, it takes approximately 50 ms forconventional imaging apparatuses as disclosed in the above-describedpublications to complete an imaging sequence. Accordingly, the time thatcan be spent on irradiation is only approximately 15 ms.

However, conventional systems as disclosed in the above-describedpublications suffer from communication delay that occurs, for example,due to CSMA/CA specified in wireless communication standards foravoiding collision of packets, and it takes a long time to send orreceive the irradiation permission request signal and the irradiationpermission signal.

When communication delay occurs, for example, an irradiation cannot becompleted within a period of time of accumulating charges in the imagingapparatus. This results in the decreased amount of radiation emitted toa frame compared to the amount of radiation in a normal condition inwhich no communication delay occurs. The decrease of radiation causes anoverall decrease of the signal values of the resultant frame image.

An analysis of dynamic behavior of a subject using frame images,particularly an analysis that focuses on temporal difference of asubject, is greatly affected by such change in the amount of radiation.

That is, when signal values are decreased only in a certain frame, thedifference of feature values between the certain frame and the previousframe thereof is greatly different from the difference of feature valuesbetween other two frames. The variation in the feature values maysometimes be erroneously recognized as an abnormality in some analysis.

Universally prevalent communication methods such as wireless LAN sufferfrom a delay of approximately 9 ms at the maximum. That is, a delay of18 ms can occur in a process of sending an irradiation permissionrequest signal and receiving a reply of an irradiation permissionsignal. In this case, radiation is not emitted at the timing ofaccumulating charges in the imaging elements, which results in a failureof serial imaging.

SUMMARY

It is an object of the present invention to provide a radiographicimaging system that includes an irradiating apparatus for generatingradiation and a radiographic imaging apparatus for generating image dataof a radiographic image based on the received radiation and that cantake a suitable measure before the operation lag between the irradiatingapparatus and the radiographic imaging apparatus becomes large enough tohave an influence on diagnosis.

To achieve at least one of the abovementioned objects, according to anaspect of the present invention, a radiographic imaging system includes:

an irradiating apparatus which generates radiation;

a first clock which keeps time and which works with the irradiatingapparatus;

a radiographic imaging apparatus which generates image data based onreceived radiation;

a second clock which keeps time and which works with the radiographicimaging apparatus; and

a hardware processor,

wherein the hardware processor

(i) obtains a clock value of the first clock at a predetermined timepoint and a clock value of the second clock at the predetermined timepoint respectively as first clock information and second clockinformation,

(ii) makes a determination as to whether a specific condition is metbased on the obtained first clock information and the obtained secondclock information, and

(iii) in response to the specific condition being met, performs aspecific output.

BRIEF DESCRIPTION OF THE DRAWINGS

The advantages and features provided by one or more embodiments of theinvention will become more fully understood from the detaileddescription given hereinbelow and the appended drawings which are givenby way of illustration only, and thus are not intended as a definitionof the limits of the present invention.

FIG. 1 is a block diagram of a radiographic imaging system according toan embodiment of the present invention, illustrating the configurationthereof.

FIG. 2 is a block diagram of a radiation controlling apparatus of theradiographic imaging system in FIG. 1 , illustrating the specificconfiguration thereof.

FIG. 3 is a block diagram of a radiographic imaging apparatus of theradiographic imaging system in FIG. 1 , illustrating the specificconfiguration thereof.

FIG. 4 is a timing chart of a basic operation of the radiographicimaging system in FIG. 1 .

FIG. 5 illustrates clock information of clocks when the imaging system100 in FIG. 1 is in operation.

FIG. 6 a block diagram of an access point of the radiographic imagingsystem in FIG. 1 , illustrating an example of the configuration thereof.

FIG. 7 is a block diagram of the radiographic imaging system accordingto the embodiment, illustrating another example of the configurationthereof.

FIG. 8 is a block diagram of a radiographic imaging apparatus in FIG. 3, illustrating the functional configuration thereof.

FIG. 9 is a block diagram of the radiation controlling apparatus in FIG.2 , illustrating the functional configuration thereof.

FIG. 10 is a timing chart of an operation of the radiographic imagingapparatus in FIG. 8 or the radiation controlling apparatus in FIG. 9 .

FIG. 11 is a timing chart of an operation of the radiographic imagingapparatus in FIG. 8 or the radiation controlling apparatus in FIG. 9 .

FIG. 12 is a timing chart of an operation of the radiographic imagingapparatus in FIG. 8 or the radiation controlling apparatus in FIG. 9 .

FIG. 13 is a block diagram the radiographic imaging apparatus of theradiographic imaging system according to the embodiment, illustratinganother example of the configuration thereof.

FIG. 14 is a timing chart of an operation of the radiographic imagingsystem in FIG. 13 .

FIG. 15 is a block diagram of the radiographic imaging apparatus of theradiographic imaging system according to the embodiment, illustratinganother example of the configuration thereof.

FIG. 16 is a block diagram of the radiographic imaging system in FIG. 15according to the embodiment, illustrating the configuration thereof.

FIG. 17 is a block diagram of the radiographic imaging system accordingto a supplementary technique, illustrating the configuration thereof.

FIG. 18 is a block diagram of the radiographic imaging apparatus of theradiographic imaging system in FIG. 17 , illustrating the specificconfiguration thereof.

FIG. 19 is a block diagram of the radiation controlling apparatus of theradiographic imaging system in FIG. 10 , illustrating the specificconfiguration thereof.

FIG. 20 is a timing chart of an example operation of the radiographicimaging system in FIG. 10 .

FIG. 21 is a timing chart of another example operation of theradiographic imaging system in FIG. 10 .

FIG. 22 is a block diagram of the radiographic imaging system accordingto Example 1-1, illustrating the configuration thereof.

FIG. 23 is a block diagram of the radiographic imaging system accordingto Example 1-2, illustrating the configuration thereof.

FIG. 24 is a block diagram the radiographic imaging system according toExample 1-3, illustrating the configuration thereof.

FIG. 25 is a block diagram of the radiographic imaging system accordingto Example 1-4, illustrating the configuration thereof.

FIG. 26 is a block diagram of the radiographic imaging system accordingto Example 1-5, illustrating the configuration thereof.

FIG. 27 is a block diagram of the radiographic imaging system accordingto Example 1-6, illustrating the configuration thereof.

FIG. 28 is a block diagram of the radiographic imaging system accordingto Example 1-7, illustrating the configuration thereof.

FIG. 29 is a block diagram of the radiographic imaging apparatus of theradiographic imaging system according to Example 1-8, illustrating thespecific configuration thereof.

FIG. 30 is a timing chart of an operation of the radiographic imagingsystem that includes the radiographic imaging apparatus in FIG. 23 .

FIG. 31 is a timing chart of an operation of the radiographic imagingsystem according to Example 1-9.

FIG. 32 is a timing chart of an operation of the radiographic imagingsystem according to Example 1-11.

FIG. 33 is a flowchart of an operation of the radiographic imagingsystem according to Example 2-1.

FIG. 34 is a flowchart of an operation of the radiographic imagingsystem according to Example 2-2.

FIG. 35 is a flowchart of an operation of the radiographic imagingsystem according to Example 2-3.

FIG. 36 is a flowchart of an operation of the radiographic imagingsystem according to Example 2-4.

FIG. 37 is a perspective view of the radiographic imaging apparatus ofthe radiographic imaging system according to Example 2-5.

FIG. 38 is a graph illustrating an operation of the radiographic imagingsystem according to Example 3-1.

FIG. 39 is a graph illustrating an operation of the radiographic imagingsystem according to Example 3-2.

FIG. 40 is a graph illustrating an operation of the radiographic imagingsystem according to Example 3-3.

FIG. 41 is a graph illustrating an operation of the radiographic imagingsystem according to Example 4-1.

FIG. 42A is a graph illustrating an operation of the radiographicimaging system that does not have the configuration of Example 4-2.

FIG. 42B is a graph illustrating an operation of the radiographicimaging system according to Example 4-2.

FIG. 43 is a flowchart illustrating an operation of the radiographicimaging system according to Example 4-3.

FIG. 44 is a graph illustrating an operation of the radiographic imagingsystem according to Example 5-1.

FIG. 45A is a graph illustrating the relationship between temperatureand clock rate, and FIG. 45B is a graph illustrating an operation of theradiographic imaging system according to Example 5-3 of first and secondinventions.

FIG. 46 is a flowchart of an operation of the radiographic imagingsystem according to Example 6-2.

FIG. 47 is a flowchart of an operation of the radiographic imagingsystem according to Example 6-3.

FIG. 48 is a flowchart of an operation of the radiographic imagingsystem according to Example 6-4.

FIG. 49 is a flowchart of an operation of the radiographic imagingsystem according to Example 6-5.

FIG. 50 is a flowchart of an operation of the radiographic imagingsystem according to Example 6-6.

FIG. 51 is a flowchart of an operation of the radiographic imagingsystem according to Example 7-1.

FIG. 52 is a flowchart of an operation of the radiographic imagingsystem according to Example 7-2.

FIG. 53 is a flowchart of an operation of the radiographic imagingsystem according to Example 7-3.

FIG. 54 is a flowchart of an operation of the radiographic imagingsystem according to Example 9-1.

FIG. 55 is a flowchart of an operation of the radiographic imagingsystem according to Example 9-2.

FIG. 56 is a block diagram of the radiographic imaging system accordingto Example 11-1, illustrating the configuration thereof.

FIG. 57 is a block diagram of the radiographic imaging system accordingto Example 11-2, illustrating the configuration thereof.

FIG. 58 is a block diagram of the radiographic imaging system accordingto Example 11-3, illustrating the configuration thereof.

DETAILED DESCRIPTION OF EMBODIMENTS

Hereinafter, one or more embodiment of the present invention will bedescribed with reference to the drawings. However, the scope of theinvention is not limited to the disclosed embodiments.

Configuration of Radiographic Imaging System

First, an overview of a radiographic imaging system (hereinafterreferred to as an imaging system 100) of the embodiment will bedescribed. FIG. 1 is a block diagram of the imaging system 100,illustrating the schematic configuration thereof.

As illustrated in FIG. 1 , the imaging system 100 of the embodimentincludes an irradiating apparatus 1, an access point (hereinafterreferred to as an AP 2) and at least one radiographic imaging apparatus(hereinafter referred to as an imaging apparatus 3).

The imaging system 100 is configured such that communication is possiblebetween the irradiating apparatus 1, and the AP 2 and between the AP 2and the imaging apparatus 3. That is, communication between theirradiating apparatus 1 and the imaging apparatus 3 is possible via theAP 2.

The imaging system 100 can communicate with a radiology informationsystem (RIS), a picture archiving and communication system (PACS) andthe like, which are not shown in the figures.

The irradiating apparatus 1 generates a radiation (X-ray radiation orthe like) and emits the radiation R to a subject S and the imagingapparatus 3 disposed behind the subject S. The irradiating apparatus 1includes a housing 11, a radiation controlling apparatus (hereinafterreferred to as a controlling apparatus 12), a radiation tube(hereinafter referred to as a tube 13), a console 14, an operating panel15 and the like.

Wired connection is established between the controlling apparatus 12 andthe tube 13, between the controlling apparatus 12 and the console 14 andbetween the console 14 and the operating panel 15 so that communicationis possible.

In response to a user operation to start an exposure, the controllingapparatus 12 applies a voltage to the tube 13 according to a presetirradiating condition.

The specific configuration of the controlling apparatus 12 will bedescribed later.

When a voltage is applied from the controlling apparatus 12, the tube 13generates the radiation R at a dose corresponding to the voltage for aperiod of time corresponding to the application time of the voltage.

That is, when the voltage is continuously applied from the controllingapparatus 12, the tube 13 continuously emits the radiation R. When thepulsed voltage is applied, the tube 13 emits the pulsed radiation R.

The console 14 is constituted by a PC, a portable terminal or adedicated device.

The console 14 is capable of performing a variety of image processing toreceived image data according to need.

The console 14, which includes a display (not shown), can display aradiographic image based on image data.

With the console 14, it is possible to set an imaging mode.

In the embodiment, there are two imaging modes of a still imaging modeand serial imaging mode, and it is possible to select one of them.

In the still imaging mode, the radiation R is emitted only once for aduration specified as an irradiating condition in response to eachexposure starting operation, and a single radiographic image isgenerated.

In the serial imaging mode, one or more pulses of the radiation R eachhaving a duration specified as the irradiating condition is emitted inresponse to each exposure starting operation, and one or moreradiographic images are generated.

With the console 14, it is possible to set the frame rate when theimaging mode is the serial imaging mode. The frame rate may be setaccording to a value input by a user or selected from options (e.g. 15frames per second (hereinafter fps), 7.5 fps, 30 fps and the like).

The operating panel 15 includes a two-button exposure switch 15 a.

The exposure switch 15 a is connected to a main body of the operatingpanel 15 in a wired manner.

In response to a user operation on the exposure switch 15 a, theoperating panel 15 sends a radiographing start signal to the controllingapparatus 12 and the imaging apparatus 3. That is, in the embodiment, auser operation of pressing down the exposure switch 15 a is one of theabove-described exposure starting operations.

The operating panel 15 may be incorporated in the controlling apparatus12 as an operation interface 15, which will be described later (asillustrated in FIG. 19 ).

The AP 2, which includes a communicator, relays communication betweenthe irradiating apparatus 1 and the imaging apparatus 3.

The communicator, which includes an antenna and a connector, can performboth wired and wireless communications.

The communicator also sends beacons to the irradiating apparatus 1 andthe imaging apparatus 3 repeatedly at predetermined intervals.

Instead of being provided separately from the irradiating apparatus 1and the imaging apparatus 3, the AP 2 may be incorporated in theirradiating apparatus 1 or the imaging apparatus 3.

The imaging apparatus 3 receives the radiation R from the irradiatingapparatus 1 to generate image data.

The details of the imaging apparatus 3 will be described later.

The imaging system 100 of the embodiment having the above-describedconfiguration can take a radiographic image of the subject S by emittingthe radiation R from the irradiating apparatus 1 to the subject S who isin front of the imaging apparatus 3.

When the still imaging mode is selected as the imaging mode on theconsole 14, a single still image is obtained. When the serial imagingmode is selected, a dynamic image composed of a series of images isobtained.

As used herein, a series of images obtained by serial imaging isreferred to as a dynamic image, and each image constituting the dynamicimage is referred to as a frame image.

FIG. 1 illustrates an example configuration of the imaging system 100 inwhich the AP 2 communicates with the irradiating apparatus 1 in a wiredmanner while the AP 2 communicates with the imaging apparatus in awireless manner. However, it is only necessary in the present inventionthat the AP 2 communicates with at least one of the irradiatingapparatus 1 and the imaging apparatus 3 in a wireless manner. Forexample, as illustrated in FIG. 17 , the AP 2 may communicate with boththe irradiating apparatus 1 and the imaging apparatus 3 in a wirelessmanner. Alternatively, the AP 2 may communicate with the irradiatingapparatus 1 in a wireless manner while the AP 2 may communicate with theimaging apparatus 3 in a wired manner.

The imaging system 100 of the embodiment having the above-describedconfiguration can be installed in a radiography room of a hospital.Alternatively, the imaging system 100 can be used as a mobile system byconfiguring the irradiating apparatus 1 as a wheeled visiting wagon.When the system is mobile, it is possible to visit a subject S (SubjectS) who cannot move around to take a radiographic image.

For example, when a radiographic table in a radiography room of ahospital is used to take a radiographic image, the imaging apparatus 3disposed in the radiographic table may be connected by a cable for wiredconnection so that the imaging apparatus 3 can send and receiveinformation to and from the irradiating apparatus 1 and receive anelectric power supply.

For example, when the cable is used for wired connection with theimaging apparatus 3 as described above, a pulse signal or a timingsignal may be included in signals for the wired connection. This allowssynchronizing the irradiating apparatus 1 with the imaging apparatus 3to take a radiographic image.

However, for example, even when an image is taken in a radiography room,it is sometimes necessary to radiograph a subject who is sitting on awheel chair or laying on a bed. In such cases, the imaging apparatus 3connected with a cable suffers from the following problems.

-   -   The cable distracts the user.    -   The cable may be detached to cause a communication failure.    -   The cable contacts with a subject, which causes hygienic        concern.

Therefore, there is a need for radiography that does not use a cable forwired connection.

When a user visits a subject along with a visiting wagon, an image istaken at a ward where the subject is cared. In such cases, an image istaken at a bed on which the subject is laying, and it is necessary toput the radiographic imaging apparatus between the subject and the bed.Therefore, the problems (the cable distracts the user, the cable may bedetached to cause communication failure, the cable contacts with asubject, which causes hygienic concern, etc.) are more serious thantaking an image in a radiography room, and it has been desired to takean image without using a cable for wired connection.

In particular, since the CR, which is a conventional technique beforeradiographic imaging apparatuses with an FPD is developed, did notrequire a cable for wired connection, there is a need for radiographythat does not use a cable for wired connection in order to achieve thesame operability as the CR.

With the imaging system 100 of the embodiment, it is possible to developa visiting wagon that satisfies the needs.

Configuration of Radiation Controlling Apparatus

Next, a specific configuration of a controlling apparatus 12 of theirradiating apparatus 1 will be described. FIG. 2 is a block diagram ofthe controlling apparatus 12, illustrating the specific configurationthereof.

As illustrated in FIG. 2 , the controlling apparatus 12 according to theembodiment includes a radiation controller 121, a high voltage generator122, a storage 123, a communicator 124, an irradiator clock 125 and thelike.

The radiation controller 121 can set radiographing conditions(conditions relating to the subject S such as a body part to beradiographed and the body shape, and conditions relating to irradiationsuch as a tube voltage, a tube current, an irradiation time and acurrent-time product) according to a control signal from the console 14or the operating panel 15. In response to receiving a radiographingstart signal from the exposure switch 15 a, the radiation controller 121sends a controlling signal to the high voltage generator 122 to startapplying a voltage (irradiation).

In response to receiving the control signal from a radiation controller,the high voltage generator 122 applies a voltage to the tube 13according to the preset irradiating conditions.

The storage 123 is constituted by a SRAM (Static RAM), an SDRAM(Synchoronous DRAM), a NAND flash memory, an HDD (Hard Disk Drive) andthe like.

The communicator 124 includes an antenna and a connector forcommunication with external devices.

The communicator 124 can select between wired communication and wirelesscommunication according to an external control signal. That is, whenselecting wireless communication, the communicator 124 performs wirelesscommunication by using the antenna. When selecting wired communication,the communicator 124 can send and receive information via a wired LAN orthe like. To perform synchronization by wired communication, forexample, a protocol such as NTP (Network Time Protocol) or the methodspecified in the international standard, the IEEE Std. 1588-2008(hereinafter referred to as the IEEE1588) can be used.

The irradiator clock 125, which serves as a second clock of the presentinvention, starts a clocking operation to generate clock informationwhen the apparatus is powered on or it receives a predetermined externalcontrol signal.

The irradiator clock 125 may output either timing information such aspulses at regular intervals or time information such as year, month,day, hour and minute and second and the number of counts that is countedup at regular intervals from a certain time point.

Instead of being incorporated in the controlling apparatus 12, theirradiator clock 125 may be provided as an external device with respectto the controlling apparatus 12.

In recent years, some LAN chips have such timer function as a defaultfunction, which is a timing synchronization function (hereinafterreferred to as a TSF) specified in the communication standards of theIEEE 802.11. This type of a wireless LAN chip can be used as theirradiator clock 125.

In the embodiment, the high voltage generator 122 is incorporated in thecontrolling apparatus 12. This allows the user to use radiation withoutconcern for the high voltage generator 122. As a result, it is possibleto use radiation with the system configuration that is less likely tohave a defect due to mismatch between components.

However, the high voltage generator 122 may not be incorporated in thecontrolling apparatus 12, but the high voltage generator 122 may beconfigured as an independent device from the controlling apparatus 12.This configuration allows the user to select a suitable device as thehigh voltage generator 122 independently from the controlling apparatus12, i.e. improves the flexibility in selection of the components.

Configuration of Radiographic Imaging Apparatus

Next, a specific configuration of the imaging apparatus 3 of the imagingsystem 100 will be described. FIG. 3 is a block diagram of the imagingapparatus 3, illustrating the specific configuration thereof.

In the embodiment, the imaging apparatus 3 is a so-called indirectimaging apparatus which obtains electric signals by converting theradiation R to an electromagnetic wave of a different wavelength such asvisible light. However, the present invention is not limited thereto,and the imaging apparatus 3 may be a so-called direct imaging apparatusthat directly converts the radiation R to electric signals withdetecting elements.

Further, the other configurations of the imaging apparatus 3 is notlimited to the example in FIG. 3 , and the imaging apparatus 3 may haveany configuration that can generate image data of a radiographic image.

As illustrated in FIG. 3 , the imaging apparatus 3 of the embodimentincludes an imaging controller 31, a radiation detector 32, a scannerdriver 33, a reader 34, a storage 35, a communicator 36, an imager clock37 and the like as well as a housing and a scintillator (not shown). Abattery 38 supplies electric power to the components 31 to 37.

On the housing, a power switch, a selector switch, an indicator, aconnector 36 of the communicator 36 (described later) and the like (notshown) are disposed.

When the Scintillator receives the radiation R, it emits anelectromagnetic wave of a longer wavelength than the radiation R such asvisible light.

The imaging controller 31 includes a computer with a CPU (CentralProcessing Unit), a ROM (Read Only Memory), a RAM (Random AccessMemory), an input/output interface and the like connected to each othervia a bus, a FPGA (Field Programmable Gate Array) and the like, whichare not shown in the figure.

The imaging controller 31 may be constituted by a dedicated controllercircuit.

The radiation detector 32 generates charges when it receives theradiation R. The radiation detector 32 includes a substrate 32 a, ascanning lines 32 b, signal lines 32 c, radiation detecting elements 32d, switching elements 32 e, bias lines 32 f, a power supply circuit 32 gand the like.

The substrate 32 a, which is formed in a plate shape, is disposedopposite and parallel to the scintillator.

The scanning lines 32 b extend parallel to each other at predeterminedintervals.

The signal lines 32 c extend parallel to each other at predeterminedintervals, which extend perpendicular to the scanning lines 32 b but arenot electrically connected to the scanning lines.

That is, the scanning lines 32 b and the signal lines 32 are disposed ina grid pattern.

The radiation detecting elements 32 d generate electric signals(currents, charges) according to the dose of radiation emitted to theradiation detecting elements (or the amount of electromagnetic waveconverted by the scintillator. The radiation detecting elements 32 d areconstituted by photodiodes or phototransistors.

The radiation detecting elements 32 d are disposed on the surface of thesubstrate 32 a respectively in the areas segmented by the scanning lines32 b and the signal lines 32 c. That is, the radiation detectingelements 32 d are arranged in a matrix. Accordingly, each of theradiation detecting elements 32 d is opposed to the scintillator.

One terminal of each radiation detecting element 32 d is connected to adrain terminal of each switching element 32 e, and the other terminal isconnected to a bias line.

As with the radiation detecting elements 32 d, the switching elements 32e are disposed in the respective areas segmented by the scanning lines32 b and the signal lines 32 c.

A gate electrode, a source electrode and a drain electrode of eachswitching element 32 e are connected respectively to an adjacentscanning line 32 b, an adjacent signal line 32 and one terminal of aradiation detecting element 32 d disposed in the same area.

The bias lines 32 f are connected to the other terminal of eachradiation detecting element 32 d.

The power supply circuit 32 g generates a reverse bias voltage andapplies it to the radiation detecting elements through the bias lines 32f.

The scanning driver 33 includes a power supply circuit 33 a, a gatedriver 33 b and the like.

The power supply circuit 33 a generates an on-voltage and anoff-voltage, which are different from each other, and supplies them tothe gate driver 33 b.

The gate driver 33 b switches the voltage to be applied to the scanninglines 32 between the on-voltage and the off-voltage.

The reader 34 includes reader circuits 34 a, an analog multiplexer 34 b,an A/D converter 34 c and the like.

The reader circuits 34 a are connected respectively to the signal lines32 c of the radiation detector 32 to apply a reference voltage to thesignal lines 32 c.

Each of the reader circuits 34 a includes an integrator circuit 34 d, acorrelated double sampling circuit (hereinafter referred to as a CDScircuit) 34 e and the like.

The integrator circuit 34 d integrates charges released to thecorresponding signal line 32 c and outputs a voltage corresponding tothe integral of the charges to the CDS circuit 34 e.

The CDS circuits 34 e samples and holds an output voltage of theintegrator circuit 34 d before the on-voltage is applied (i.e. while theoff-voltage is applied) to a scanning line 32 b connected to radiationdetecting elements 32 d from which a signal is to be read, so as tooutput the difference of an output voltage of the integrator circuit 34d after the on-voltage is applied to the scanning line 32 b to read asignal charge of the radiation detecting element and then theoff-voltage is applied to the scanning line 32 b.

The analog multiplexer 34 b sequentially outputs differential signalsfrom the CDS circuits 34 e to the A/D converter 34 c one by one.

The A/D converter 34 c sequentially converts input image data composedof analog voltages to image data composed of digital values.

The storage 35 is constituted by an SRAM (Static RAM), an SDRAM(Synchronous DRAM), a NAND flash memory, an HDD (Hard Disk Drive) andthe like.

The communicator 36 includes an antenna 36 a and a connector 36 b forcommunication with external devices.

The communicator 36 can select between wired communication and wirelesscommunication according to an external control signal. That is, whenselecting wireless communication, the communicator 36 performs wirelesscommunication by using the antenna 36 a. When selecting wiredcommunication, the communicator 36 can send and receive information viaa wired LAN or the like. To perform synchronization by wiredcommunication, for example, a protocol such as NTP (Network TimeProtocol) or the method specified in the IEEE 1588 can be used.

The imager clock 37, which serves as a second clock of the presentinvention, starts a clocking operation to generate clock informationwhen the apparatus is powered on or it receives a predetermined controlsignal.

The imager clock 37 may output either timing information such as pulsesat regular intervals, or time information such as year, month, day,hour, minute and second and the number of counts that is counted up atregular intervals from a certain time point.

Instead of being incorporated in the imaging apparatus 3, the imagerclock 37 may be provided as an external device with respect to theimaging apparatus 3.

In recent years, some LAN chips have such timer function as a defaultfunction, which is a timing synchronization function (hereinafterreferred to as a TSF) specified in the communication standards of theIEEE 802.11. Accordingly, this type of wireless LAN chip can be used asthe imager clock 37.

When the power of the imaging apparatus 3 having the above-describedconfiguration is turned on, the imaging apparatus 3 puts itself into oneof an “initialized state”, an “accumulating state” and a “reading andtransferring state”. The timing of switching the state will be describedlater.

In the “initialized state”, the on-voltage is applied to each of theswitching elements 32 e so that charges generated in the radiationdetecting elements 32 d are not accumulated in the respective pixels(i.e. the charges are released to the signal lines 32 c).

In the “accumulating state”, the off-voltage is applied to each of theswitching elements 32 e so that charges generated in the radiationdetecting elements 32 d can be accumulated in the respective pixels(i.e. the charges are not released to the signal lines 32 c).

In the “reading and transferring state”, the on-voltage is applied toeach of the switching elements 32 e, and the reader 34 is driven to readimage data from received charges so that the reader 34 can send theimage data to the other devices.

Depending on the configuration of the elements and the apparatus,accumulated charges are cleared in the reading step. In such cases,“reading” and “initializing” are not distinguished from each other asseparate steps, but “reading” and “initializing” are performedsimultaneously as a single step.

Imaging Operation of Radiographic Imaging System

Next, a basic imaging operation of the imaging system 100 will bedescribed. FIG. 4 is a timing chart of an operation of the imagingsystem 100, and FIG. 5 illustrates the clock information of the clockswhen the imaging system 100 is in operation.

First, when an action is performed which triggers the clocking operationof the irradiator clock 125 of the controlling apparatus 12 and theclocking operation of the imager clock 37 of the imaging apparatus 3(e.g. when the apparatuses of the imaging system 100 is powered on), theirradiator clock 125 and the imager clock 37 individually start therespective clocking operations.

In this step, the irradiator clock 125 may start the clocking operationat a different timing from the imager clock 37. However, the clockinformation of one clock is synchronized with the clock information ofthe other clock based on the clock information of the other clock orclock information of a clock that is synchronized with the other clock.

Then, when the user presses down the exposure switch 15 a of theirradiating apparatus 1, the irradiating apparatus 1 sends aradiographing start signal to the controlling apparatus 12 and theimaging apparatus 3.

When the clock information (time information) of the imager clock 37reaches a first predetermined value (t1) (i.e. a first predeterminedtime (t1) has elapsed since the start of the clocking operation), theimaging apparatus 3 performs initialization by applying the on-voltageto the switching elements 32 e to release dark charges accumulated inthe pixels to the signal lines 32 c.

Then, when the clock information of the imager clock 37 reaches a secondpredetermined value (t2) that is greater than the first predeterminedvalue (i.e. a second predetermined time (t2) has elapsed since the startof the clocking operation), the imaging apparatus 3 applies theoff-voltage to the scanning lines 32 b so that charges generated by theradiation detecting elements 32 d can be accumulated in the respectivepixels. This charge accumulable state is maintained until the clockinformation of the imager clock 37 reaches a fourth predetermined value(t4) that is greater than the second predetermined value (i.e. a fourthpredetermined time has elapsed from the start of the clockingoperation).

When the clock information of the irradiator clock 125 of thecontrolling apparatus 12 reaches a third predetermined value (t3) thatis greater than the second predetermined value but less than the fourthpredetermined value (i.e. a third predetermined time has elapsed fromthe start of the timing operation), the irradiating apparatus 1 emitsthe radiation R to the subject S and the imaging apparatus 3 behind thesubject S. That is, the irradiating apparatus 1 emits the radiation whenthe imaging apparatus 3 can accumulate charges (between t2 and t3).

When the imaging apparatus 3 receives the radiation R, it generatescharges by the radiation detecting elements 32 d of the radiationdetector 32 and accumulate the charges in the respective pixels.

When the clock information of the imager clock 37 reaches the fourthpredetermined value (t4) that is greater than the third predeterminedvalue (i.e. a fourth predetermined time (t4) has elapsed since the startof the clocking operation), the imaging apparatus 3 applies theon-voltage to the TFTs 35 connected to the scanning lines 32 b torelease charges accumulated in the pixels to the signal lines 32 c inthe same way as the initialization. Then, the imaging apparatus 3 readsimage data from the released charges by the reader 34.

Depending on the configuration of the radiation detecting elements ofthe imaging apparatus 3, initialization by releasing accumulated chargesmay be performed in the charge reading step.

When the imaging mode is the serial imaging mode, the irradiatingapparatus 1 and the imaging apparatus 3 repeat the above-describedseries of steps based on the clock information of a TSF timer 22 and theimager clock 37 for the same times as the number of frame images to betaken.

Time Difference of Clocks

While the imaging system 100 is in operation as described above, forexample, there may sometimes be a slight difference in clock ratebetween the irradiator clock 125 of the controlling apparatus 12 and theimager clock 37 of the imaging apparatus 3 due to the frequency error ofan oscillator of the controlling apparatus 12 or the imaging apparatus 3or the like. When a relatively lengthy imaging process such as serialimaging is performed in such cases, the time difference between theclock information of the irradiator clock 125 and the clock informationof the imager clock 37 is incrementally increased, for example, asillustrated in FIG. 5 . This causes a time lag between the operationtiming of the irradiating apparatus 1 and the operation timing of theimaging apparatus 3.

To prevent this, the imaging system 100 of the embodiment takes asuitable measure before the time lag of the operation timing between theirradiating apparatus 1 and the imaging apparatus 3 becomes large enoughto have an influence on diagnosis.

To check the length of the time lag, a first clock information as astandard and a second clock information as a target for comparison arerequired.

For example, the first clock information can be generated by thefollowing methods.

Method for Generating First Clock Information 1

A first generating method uses the time information of the timingsynchronization function (hereinafter referred to as the TSF) specifiedin the IEEE 802.11 communication standard as the first clockinformation.

The “TSF” is a function of synchronizing the time between an accesspoint and devices when the devices communicate with each other in awireless manner.

Specifically, the access point is provided with a free running clock(TSF timer) that counts up periodically (at 1 μs intervals) to sendperiodic beacons along with the information on the sent time (normallyevery 100 ms).

Further, each of the terminals are also provided with a clock thatcounts up periodically (at 1 μs intervals). When the terminals receive abeacon, it updates the time information of the own clock 125, 37according to the time information included in the beacon and continuesthe counting up operation.

When the time information of the TSF is used as the first clockinformation, the AP 2 is provided with a TSF timer 22, and thecommunicator 21 of the AP 2 outputs the beacons including the timeinformation to the controlling apparatus 12 and the imaging apparatus 3,for example, as illustrated in FIG. 6 .

For example, the TSF timer 22 counts up from 0. When the timeinformation reaches a predetermined maximum value, it resets the numberto 0 and counts up from 0 again.

The TSF timer 22 may output the clock information that is generatedindependently from the controlling apparatus 12 or the imaging apparatus3. Alternatively, the TSF timer 22 may output the clock information thatis synchronized with the clock information of the controlling apparatus12 or the imaging apparatus 3.

The time information of the TSF timer 22 included in each beacon, i.e.the time information of the TSF timer 22 at the time of sending eachbeacon, is used as the first clock information.

In this configuration, the TSF timer 22 serves as the first clock of thepresent invention.

Hereinafter, when the TSF is utilized as the first clock information,the AP 2 is referred to as a clock information source apparatus 2.

Method for Generating First Clock Information 2

A second generating method uses a dedicated apparatus that outputs thefirst clock information.

Specifically, as illustrated in FIG. 7 for example, the system includesa clock information source apparatus 4 that includes a clock (not shown)and that can communicate clock information with the controllingapparatus 12 and the imaging apparatus 3.

The clock (not shown) is incorporated in the clock information sourceapparatus 4.

The clock of the clock information source apparatus 4 may output theclock information that is generated independently from the controllingapparatus 12 or the imaging apparatus 3. Alternatively, the TSF timer 22may output the clock information that is synchronized with the clockinformation of the controlling apparatus 12 or the imaging apparatus 3.

The clock information source apparatus 4 may output either timinginformation such as pulses at regular intervals or time information suchas year, month, day, hour, minute and second and a number that iscounted up at regular intervals from a certain time point.

The clock information source apparatus 4 periodically sends thegenerated clock information as the first clock information.

In this configuration, the clock information source apparatus 4 servesas the first clock of the present invention.

In the following, the TSF timer 22 of the AP 2 or the clock (not shown)of the clock information source apparatus 4 is also referred to as areference clock.

Obtainment of Second Clock Information

The controller of the controlling apparatus 12 or the imaging apparatus3 that receives the first clock information from the clock informationsource apparatus 2, 4 obtains as the second clock information the clockinformation of the irradiator clock 125 or the imager clock 37 at thetime of receiving (obtaining) the first clock information from the clockinformation source apparatus 2, 4. That is, in the present embodiment,the time of receiving the first clock information is the predeterminedtime point of the present invention.

Particularly in the present embodiment, the first clock information andthe second clock information are obtained at two or more predeterminedtime points at least in a part of an imaging period. That is, in thepresent embodiment, the at least a part of the imaging period is thespecific period of the present invention.

The specific period may be set to a desired length according to a useroperation.

FIG. 8 illustrates a configuration of the imaging apparatus 3 forcorrecting the clock information of the own clock 37 and outputting itto the imaging controller 31, and FIG. 9 illustrates a configuration ofthe controlling apparatus 12 for correcting the clock information of theown clock 125 and outputting it to the radiation controller 125.

The imaging apparatus 3 or the controlling apparatus 12 that obtains thefirst clock information includes a clock controller 3 a, 12 a. The clockcontroller 3 a, 12 a is connected to the own clock 125, 37 to obtain thesecond clock information (time information or timing information) fromthe own clock 125, 37.

Further, the clock controller 3 a, 12 a is connected to the owncommunicator 124, 36 so as to be able to obtain the first clockinformation (time information or timing information) from the clockinformation source apparatus 2, 4.

The clock controller 3 a, 12 a may be constituted by a dedicatedsemiconductor, a circuit board or an apparatus or may be incorporated ina general-purpose processor (including the radiation controller 121 orthe imaging controller 31) such as a CPU or a FPGA as one of thefunctions thereof.

In the clock controller 3 a, 12 a, setting information on the timinginformation or the time information of the clock information sourceapparatus 2, 4 may be previously stored.

In the configuration in which the clock information source apparatus 2,4 outputs timing information as the first clock information, when theinterval of outputting the timing information (pulses or the like) fromthe clock information source apparatus 2, 4 is set to, for example, xseconds, the interval of obtaining the external first clock informationcan be set to x seconds.

In the configuration in which the clock information source apparatus 2,4 outputs time information as the first clock information, when theinterval of outputting the time information (time, the number of countsthat is counted up by the clock information source apparatus 4 from acertain time point, etc.) from the clock information source apparatus 2,4 is set to x seconds, the interval of obtaining the external clockinformation can be set to x seconds.

In particular, when the time information is a count-up value counted bythe clock information source apparatus 4, the clock controller 3 a, 12 acan obtain the counting interval of the clock information sourceapparatus 4 and store it. For example, when the counting frequency ofthe clock information source apparatus 2, 4 is y Hz, the clockcontroller 3 a, 12 a can previously obtain a counting interval of 1/yseconds and store it.

Combination of Time Lag Checking Methods

As described above, in the present embodiment, the first clockinformation generated by the clock information source apparatus 2, 4 iseither time information or timing information. Similarly, the secondclock information obtained by the irradiator clock 125 or the imagerclock 37 is either time information or timing information.

Accordingly, depending on the configuration, the first clock informationand the second clock information may be compared by any one of thefollowing four methods to check the time difference.

1. Comparison of timing information with timing information

2. Comparison of timing information with time information

3. Comparison of time information with timing information

4. Comparison of time information with time information

In the following, each of the methods for checking the time differencebetween the first clock information and the second clock informationwill be described in detail.

Method of Checking Clock Information Lag by Comparing Timing Informationwith Timing Information

FIG. 10 and FIG. 11 illustrate an operation of the controlling apparatus12 or the imaging apparatus 3 that receives the first clock information.

Assuming that the clock information source apparatus 2, 4 is configuredas the first clock to generate timing information while the clockcontroller 3 a, 12 a is configured as the second clock to obtain timinginformation. In the example illustrated in FIG. 10 and FIG. 11 , theclock controller 3 a, 12 a counts the number of pulses of the own clock125, 37 in the period after an input of the timing information from theclock information source apparatus 2, 4 until the next input of thetiming information (i.e. the period after the reception of the (N−1)thpulse until the reception of the N-th pulse) and determines the clockrate of the own clock 125, 37 relative to the clock rate of the clockinformation source apparatus 2, 4.

For example, when the output cycle of the first clock information fromthe clock information source apparatus 2, 4 is set to 1 second while thefrequency of the own clock 125, 37 is set to 10 MHz, 10000000 pulses arecounted per second.

However, in practice, the pulse generating rate fluctuates due to theinstability of the clock of the clock information source apparatus 2, 4,the insufficient precision of the imager clock 37 or the irradiatorclock 125, a change in temperature and the like, and the number ofpulses is not exactly equal to 10000000 but is deviated.

The difference is the clocking difference between the clock of the clockinformation source apparatus 4 and the clock the imaging apparatus 3 orthe controlling apparatus 12.

For example, in the example in FIG. 10 , assuming that the number ofpulses after reception of the (N−1)th pulse until reception of the N-thpulse is 10000010, which is greater than the specified value by 10, itcan be understood that the own clock 125, 37 is faster by 10/10000000than the clock information source apparatus 4.

For another example, in the example in FIG. 11 , assuming that thenumber of pulses after reception of the (N−1)th pulse until reception ofthe N-th pulse is 9999990, which is less than the specified value by 10,it can be understood that the own clock 125, 37 is slower by 10/10000000than the clock information source apparatus 4.

Method of Checking Clock Information Lag by Comparing Timing Informationwith Time Information

Assuming that the clock information source apparatus 2, 4 is configuredas the first clock to generate timing information while the clockcontroller 3 a, 12 a is configured as the second clock to generate timeinformation. In the example illustrated in FIG. 10 and FIG. 11 , theclock controller 3 a, 12 a generates time information from timinginformation such as pulses of the own clock 125, 37 in the period afteran input of the timing information from the clock information sourceapparatus 2, 4 until the next input of the timing information (i.e. theperiod after the reception of the (N−1)th pulse until the reception ofthe N-th pulse) and determines the clock rate of the own clock 125, 37relative to the clock rate of the clock information source apparatus 4from the generated time information.

For example, when the output cycle of the first clock information fromthe clock information source apparatus 2, 4 is set to 1 second while thefrequency of the own clock 125, 37 is set to 10 MHz, 10000000 pulses aregenerated per second. That is, a pulse is generated in every 0.0000001second. By correcting the time information by 0.0000001 seconds withrespect to each pulse, the time information at each timing can beobtained.

The correction of the time information may be performed with respect toeach pulse or each set of pulses. Alternatively, the correction of thetime information may be performed when there is a request for the timeinformation.

By repeating the above-described correction of the time information over1 second, the time information becomes 1 second.

However, in practice, the pulse generating rate fluctuates due to theinstability of the clock of the clock information source apparatus 2, 4,the insufficient precision of the imager clock 37 or the irradiatorclock 125, a change in temperature and the like, and the timeinformation does not become exactly 1 second but is deviated.

The difference is the clocking difference between the clock of the clockinformation source apparatus 4, and imager clock 37 or the irradiatorclock 125.

For example, in the case in FIG. 10 , assuming that the number of pulsesafter the reception of the (N−1)th pulse until the reception of the N-thpulse is 10000010, which is greater than the specified value by 10, theperiod of time after the reception of the (N−1)th pulse until thereception of the N-th pulse is 1.000001 second. Accordingly, it can beunderstood that the clock rate of the own clock 125, 37 is faster by0.000001 second per 1 second than the clock rate of the clockinformation source apparatus 4.

For example, in the example in FIG. 11 , assuming that the number ofpulses after the reception of the (N−1)th pulse until the reception ofthe N-th pulse is 9999990, which is less than the specified value by 10,the period of time after reception of the (N−1)th pulse until thereception of the N-th pulse is 0.999999 second. Accordingly, it can beunderstood that the clock rate of the own clock 125, 37 is slower by0.000001 second per 1 second than the clock rate of the clockinformation source apparatus 4.

Method of Checking Clock Information Lag by Comparing Time Informationwith Timing Information

FIG. 12 illustrates the controlling apparatus 12 or the imagingapparatus 3 that receives the first clock information.

Assuming that the clock information source apparatus 2, 4 is configuredas the first clock to generate time information while the clockcontroller 3 a, 12 a is configured as the second clock to obtain timinginformation. In the example illustrated in FIG. 12 , the clockcontroller 3 a, 12 a counts the number of pulses of the own clock 125,37 in the period of time after an input of the time information from theclock information source apparatus 2, 4 until the next input of the timeinformation (i.e. the period of time after the reception of the (N−1)thtime information until the reception of the N-th time information) anddetermines the clock rate of the own clock 125, 37 relative to the clockrate of the clock information source apparatus 2, 4.

For example, the clock controller 3 a, 12 a can obtain the length oftime (period) from (N−1) to (N) as the time information from the clockinformation source apparatus 2, 4 by obtaining the time information atthe time point (N−1) and the time information at the time point (N) andcalculating the difference between the two time information.

When the clock controller 3 a, 12 a obtains the clock information at thetime point (N−1) and the clock information at the time point (N) as thetime information from the own clock 125, 37, the clock controller 3 a,12 a can obtain the period of time from the time point (N−1) to the timepoint (N) by multiplying the counting interval of the clock informationsource apparatus 4 by the difference between the clock information atthe time point (N−1) and the clock information at the time point (N).

Then, the clock controller 3 a, 12 a compares the period of time fromthe time point (N−1) to the time point (N) with the product of thenumber of pulses in the period of time and the pulse interval of the ownclock 125, 37 so as to be able to determine the clock rate of the ownclock 125, 37 relative to the clock rate of the clock information sourceapparatus 4.

Method of Checking Clock Information Lag by Comparing Time Informationwith Time Information

Assuming that the clock information source apparatus 2, 4 is configuredas the first clock to generate time information while the clockcontroller 3 a, 12 a is configured as the second clock to obtain timeinformation. In the example illustrated in FIG. 12 , the clockcontroller 3 a, 12 a can obtain the length of time (period) from thetime point (N−1) to the time point (N) as the time information from theclock information source apparatus 2, 4 by obtaining the timeinformation at the time point (N−1) and the time information at the timepoint (N) from the clock information source apparatus 2, 4 andcalculating the difference between the two time information.

At the same time, the clock controller 3 a, 12 a can obtain the periodof time from the time point (N−1) to the time point (N) as the timeinformation from the own clock 125, 37 by obtaining the time informationat the time point (N−1) and the time information at the time point (N)from the own clock 125, 37 and calculating the difference between thetwo time information.

Then, the clock controller 3 a, 12 a compares the period of time fromthe time point (N−1) to the time point N based on the first clockinformation with the period of time from the time point (N−1) to thetime point N based on the second clock information so as to be able todetermine the clock rate of the own clock 125, 37 relative to the clockrate of the clock information source apparatus 4.

By comparing the first clock information with the second clockinformation by any one of the above-described four methods, the clockcontroller 3 a, 12 a can determine the clock rate of the own clock 125,37 relative to the clock rate of the clock information source apparatus2, 4.

Determination as to Whether Particular Condition is Met

The imaging controller 31 makes a determination as to whether aparticular condition is met based on the obtained first clockinformation and the second clock information.

In the present embodiment, for example, the imaging controller 31 makesa determination as to whether the accuracy of the clocks is sufficientby at least one of the following Determination Method 1 to DeterminationMethod 3. When the clock accuracy is insufficient, the imagingcontroller 31 determines that the particular condition is met.

Clock Accuracy Determination Method 1 (Difference)

When the time difference (time lag) between the first clock informationand the second clock information is used for the determination of theclock accuracy, the imaging controller 31 calculates the differencebetween the obtained first clock information and the second clockinformation and makes a determination as to whether the difference isgreater than a specific value. When the difference is greater than thespecific value, the imaging controller 31 determines that the clockaccuracy is insufficient, i.e. the particular condition is met.

Clock Accuracy Determination Method 2 (Amount of Change)

When the change of the time difference (time lag) is used for thedetermination, for example, the imaging controller 31 calculates thedifference between the first clock information and the second clockinformation and stores the difference in the storage 35 every time itobtains the first clock information and the second clock information.Then, the imaging controller 31 calculates the amount of change betweenthe stored previous difference and the latest difference and makes adetermination as to whether the calculated amount of change is greaterthan a previously calculated amount of change. When the latest amount ofchange is greater than the previous amount of change, the imagingcontroller 31 determines that the clock accuracy is insufficient, i.e.the particular condition is met.

When a predicted difference is used for the determination, for example,the imaging controller 31 may calculate the difference between theobtained first clock information and the second clock information andthe amount of change of the difference and store them in the storage 35.Then, when the difference and the amount of change stored in the storage35 indicate that the difference changes in a similar manner continuouslyfor a predetermined period of time (e.g. an imaging period), the imagingcontroller 31 may make a determination as to whether the change isgreater than a specific value.

To determine whether the particular condition is met, the differencebetween the first clock information and the second clock information andthe amount of change thereof may be directly used as described above.Instead, the average value may be calculated, or the state of change ora future predicted value may be calculated by linear interpolation,spline interpolation or the like.

To calculate the average, for example, the imaging controller 31calculates the difference between the obtained first clock informationand the second clock information and stores it in the storage 35. Then,the imaging controller 31 calculates the average of stored differences.The amount of change of the difference may sometimes change drastically.By calculating the average, it is possible to cope with such drasticchanges.

Parameters required for linear interpolation or spline interpolation canbe determined by the least-square method or the like. Regarding suchtechniques for making the determination, interpolation or extrapolationtechniques used in the other fields may be applied to make an advanceddetermination.

Specific Output

When it is determined that the particular condition is met, the clockcontroller 3 a, 12 a performs a specific output.

Examples of the specific output of the present embodiment includes thefollowing outputs.

Specific Output 1 (Correction of Clock Information)

When it is determined that the particular condition is met, the clockcontroller 3 a, 12 a corrects the operation of the timer 125, 37 so asto reduce the difference between the first clock information of theclock information source apparatus 2, 4 and the clock information of theown clock 125, 37.

To correct the operation, for example, the timing information or thetime information may be corrected as described below.

Correction of Timing Information

In the example in FIG. 10 and FIG. 11 , the clock controller 3 a, 12 achecks the clock rate of the own clock 125, 37 in the period of timeafter the reception of the (N−1)th clock information until the receptionof the N-th clock information by the above-described methods. Forexample, when the clock controller 3 a, 12 a determines that theparticular condition is met, it may correct the timing information ofthe own clock 125, 37 in the period of time after the reception of theN-th timing information until the reception of the (N+1)th timinginformation.

To correct the timing information, for example, a pulse may be removedor added with respect to a certain period of time according to thedetected difference of the clock rate as illustrated in FIG. 10 .

For example, in the example in FIG. 10 , when the number of pulses inthe period of time after the reception of the (N−1)th pulse until thereception of the N-th pulse is 10000010, which is greater than thespecified value by 10, the clock controller 3 a, 12 a may remove onepulse in every 1000000 pulses in the period of time after the receptionof the N-th pulse until reception of (N+1)th pulse. Alternatively, theclock controller 3 a, 12 a may slow down the pulse generation to reducethe number of pulses.

For another example, in the example in FIG. 11 , when the number ofpulses in the period of time after the reception of the (N−1)th pulseuntil the reception of the N-th pulse is 9999990, which is less than thespecified value by 10, the clock controller 3 a, 12 a may count onepulse in every 100000 pulses as two pulses in the period of time afterreception of the N-th pulse until reception of (N+1)th pulse.Alternatively, the clock controller 3 a, 12 a may speeds up the pulsegeneration to increase the number of pulses.

Alternatively, the clock controller 3 a, 12 a may correct the pulseinterval.

For example, when a CR oscillator circuit or an LC oscillator circuit isused as a pulse source, it is possible to readily adjust the pulseinterval by changing the property of C (capacitor), R (resistor) and L(coil).

Correction of Time Information

The clock controller 3 a, 12 a checks the clock rate of the own clock125, 37 in the period of time after the reception of the (N−1)th clockinformation until the reception of the N-th clock information by theabove-described methods. When the clock controller 3 a, 12 a determinesthat the particular condition is met, it may correct the timeinformation of the own clock 125, 37 in the period of time after thereception of the N-th time information until the reception of the(N+1)th time information.

As described above, regardless of whether the clock information that theclock information source apparatus 2, 4 sends is timing information ortime information, and regardless of whether the clock information to becorrected by the clock controller 3 a, 12 a is timing information ortime information, it is possible to suitably correct the clock rate ofthe timer 125, 37 according to the difference relative to the clock rateof the clock information source apparatus 2, 4 by the above-describedmethods.

Specific Output 2 (Warning of Clock Accuracy Lag and Imaging Permission)

When it is determined that the particular condition is met, for example,the controller 31, 121 performs at least one of the following actions.

-   -   Notify to a user that the clock information has not been        corrected for a predetermined period of time.    -   Notify that imaging is disabled.    -   Prohibit imaging.    -   Allow a user to select whether to cancel the imaging process.    -   Cancel the imaging process.

The controller 31, 121 can give the notification by displaying a messageor the like on the display or by light, sound, vibration or the like.

To disable imaging or to cancel the imaging process, the radiationcontroller 121 stop sending a control signal to the high voltagegenerator 122, sends a signal representing an instruction to cancel theimaging process to the high voltage generator 122, or the like.

To allow a user selection, for example, the controller 31, 121 displaysoptions on the display and follows a user operation that is input on theoperation interface.

At least one of the above-described actions such as the notification andthe cancellation of the imaging process may be performed at the sametime with allowing a user selection.

Alternatively, after cancelling imaging, the controller 31, 121 may alsocorrect the clock information of the imager clock 37 based on the clockinformation of the clock information source apparatus 2, 4.

Some typical radiographic imaging systems can synchronize an irradiatingapparatus with a radiographic imaging apparatus by correcting clockinformation of a second clock every time clock information isperiodically sent to the second clock from a first clock that issynchronized with the irradiating apparatus.

In a serial imaging process, such radiographic imaging apparatusesrepeat the steps of accumulating charges in an image receiver, which aremainly generated by radiation, reading and transferring the accumulatedcharges and initializing the image receiver.

For example, when the clock information of the first or second clock iscorrected, the length of time of accumulating charges in pixels intaking a certain frame image may sometimes become different from thelength of the accumulation time in taking the other serial frame images.In this case, the amount of charges accumulated in the image receiver ischanged according to the difference of the length of time.

For example, when the length of the accumulation time in taking acertain frame image becomes longer than the length of the accumulationtime in taking the other serial frame images as a result of correctingthe clock information of the clock, the image receiver receives theimage for a longer time in taking the certain frame image than in takingthe other serial frame images. That is, the image receiver accumulatescharges for a longer time than the accumulation time in taking the otherserial frame images.

To cope with the problem, for example, the irradiating apparatus may becontrolled to emit pulsed radiation only during a part of theaccumulation period. With this configuration, it is possible to even outthe amount of radiation from the irradiating apparatus in eachaccumulation time even when the length of accumulation time varies.

However, the image receiver generates and accumulates charges even byscattered radiation emitted from the outside or a subject S in additionto the radiation emitted from the radiation irradiating apparatus. Toremove such scattered radiation, a grid may sometimes be providedbetween the subject S and the image receiver. However, the grid cannotremove scattered radiation completely. That is, even when theirradiating apparatus is controlled to emit radiation only during a partof the accumulation period, reception of scattered radiation, i.e.accumulation of charges, cannot be eliminated. When the time of theclock is changed so that the length of accumulation time in taking acertain frame image becomes different from the length of accumulationtime in taking the other serial frame images, only the certain frameimage, which is taken when the time of the clock is changed, is affectedby the scattered radiation to a different degree from the other serialframe images.

In contrast, the imaging system 100 of the present embodiment isconfigured such that when the first clock information is sent from theclock information source apparatus 2, 4, the imaging apparatus 3 makes adetermination as to whether the particular condition is met. Only if theparticular condition is met, the clock information of the imager clock37 (second clock) is corrected. Therefore, the imaging system can take asuitable measure only at suitable timing, for example, when thedifference of the clock information between the clocks is increased tosuch a level that affects the contents of an image (diagnosis).

Clock Accuracy Determination Method 4

In order that the imaging system 100 according to the embodimentperforms the above-described operations, communication is establishedbetween the clock information source apparatus 2, 4 and the apparatus(at least one of the controlling apparatus 12 and the imaging apparatus3) that receives the first clock information. Depending on theenvironment in which the imaging system 100 is used, the communicationcannot be established (the above-described operations are notperformed), and an operation lag sometimes occurs between theirradiating apparatus 1 and the imaging apparatus 3.

To cope with the problem, the imaging system 100 of the embodiment mayhave the following function of detecting such operation lags.

Specifically, the controlling apparatus 12 or the imaging apparatus 3that receives the first clock information includes a second imager clock39A that performs a counting operation in synchronization with theimaging apparatus 3A as illustrated in FIG. 13 in addition to the imagerclock 37.

The clock controller 3 a, 12 a has a function of resetting the clockinformation of the second imager clock 39A when the clock controller 3a, 12 a receives the first clock information from the clock informationsource apparatus 2, 4.

When the second imager clock 39A is reset, it starts the countingoperation from an initial value again.

The clock controller 3 a, 12 a has a function of determining as towhether the clock information of the second imager clock 39A is greaterthan a predetermined threshold.

The imaging system 100 of the present embodiment having theabove-described configuration operates as follows. While there is noabnormality in the communication between the clock information sourceapparatus 2, 4 and the imaging apparatus 3A (between t0 and t1), theclock information does not exceed the threshold since the clockinformation of the second imager clock 39A is repeatedly reset asillustrated in FIG. 14 every time the imaging apparatus 3A receives thefirst clock information. When an abnormality occurs in the communicationbetween the clock information source apparatus 2, 4 and the imagingapparatus 3A so that the first clock information cannot be received fromthe clock information source apparatus (between t1 and t2), the imagerclock 37 does not correct the clock information, and the second imagerclock 39A continues the counting operation without resetting the clockinformation. Thereafter, when the clock information of the second imagerclock 39A exceeds a threshold (t3), the imaging apparatus 3A understandsthat the clock information of the imager clock has not been corrected bythe first clock information of the clock information source apparatus 2,4 for a predetermined period of time. Then, the imaging apparatus 3Aoutputs the understanding.

At the same time with outputting the understanding, the imagingapparatus 3A may perform at least one of the following actions, whichare the same actions that are performed when the particular condition ismet in the above-described embodiment.

-   -   Inform a user the clock information has not been corrected for a        predetermined period of time.    -   Notify that imaging is disabled.    -   Disable imaging.    -   Allow a user to select whether to cancel the imaging process.    -   Cancel the imaging process.

Thereafter, when the communication is recovered so that the first clockinformation is received, the second imager clock 39A resets the clockinformation (t4), and the imaging system 100 gets back to the normaloperation.

In the imaging system 100 according to the embodiment having theabove-described configuration, when the clock information of the clock37, 125 has not been corrected with the first clock information for acertain period of time, it is possible to understand it or to measurethe length of time by using the second imager clock 39A.

Further, a determination is made as to whether the time differencebetween the clock information of the first clock and the clockinformation of the imager clock falls within an allowable range bycomparing the clock information of the second imager clock with thethreshold. If the time difference is out of the allowable range, it ispossible to take a suitable measure.

Clock Accuracy Determination Method 5

As described above, a failure of establishing communication sometimescause an operation lag between the irradiating apparatus 1 and theimaging apparatus 3 depending on the environment in which the imagingsystem 100 is used. To cope with the problem, that the imaging system100 of the embodiment may have a function of detecting the operation lagin the following way.

Specifically, the controlling apparatus 12 or the imaging apparatus 3that receives the first clock information includes a memory 39B asillustrated in FIG. 15 instead of the second imager clock 39A.

When the first clock information is received from the clock informationsource apparatus 2, 4, the memory 39B stores the received first clockinformation, i.e. the corrected clock information of the imager clock37.

Instead of providing the memory 39B, the same function may be impartedto the storage 35.

The clock controller 3 a, 12 a has a function of making a determinationas to whether the difference between the clock information of the imagerclock 37 and the value stored in the memory 39B is greater than apredetermined threshold.

In the imaging system 10 of the embodiment having the above-describedconfiguration, when there is no abnormality in the communication betweenthe clock information source apparatus 2, 4 and the imaging apparatus 3B(between t0 and t1), the memory 39B stores the first clock informationevery time the imaging apparatus 3B receives the first clock informationas illustrated in FIG. 16 . Therefore, the difference between the clockinformation of the imager clock 37 and the first clock information inthe memory 39B does not exceed the threshold. However, when anabnormality occurs in the communication between the clock informationsource apparatus 2, 4 and the imaging apparatus 3B so that the firstclock information cannot be received from the clock information sourceapparatus 2, 4 (between t1 and t2), the imager clock 37 does not correctthe clock information, and the first clock information in the memory 39Bis no updated. Thereafter, when the difference between the clockinformation and the old first clock information in the memory 39Bexceeds the threshold, the imaging apparatus 3B understands that theclock information of the imager clock has not been corrected by thefirst clock information of the clock information source apparatus 2, 4for a predetermined period of time. Then, the imaging apparatus 3Boutputs it as with the imaging apparatus 3 of the present invention.

At the same time with outputting the understanding, the imagingapparatus 3A may perform at least one of the following operations, whichare the same actions as those performed when the particular condition ismet described in the “clock accuracy determination method 4”.

Thereafter, when the communication is recovered so that the first clockinformation is received, the first clock information the in memory 39Bis updated, and the imaging system 100 gets back to the normaloperation.

In the imaging system 100 according to the embodiment having theabove-described configuration, when the clock information of the clock37, 125 has not been corrected by the first clock information for apredetermined period of time, it is possible to detect it without usingthe second imager clock 39A, i.e. with a smaller number of clocks thanthe first embodiment.

In the foregoing, the imaging system 100 of the embodiment is described.In addition to the configuration in FIG. 1 , the imaging system 100 mayhave a variety of other configurations with regard to the connection ofthe clock information source apparatus 2, 4, the radiation controllingapparatus 12, the console 14, the operation interface 15 and theexposure switch 15 a.

For example, the operation interface 15 may be connected only to theconsole 14, and signals corresponding to user operations on theoperation interface 15 may be inputted to the controlling apparatus 12via the console 14.

For another example, it is not necessary that the clock informationsource apparatus 2, 4 is connected to both the controlling apparatus 12and the console 14. The clock information source apparatus 2, 4 may beconnected only to the console 14 to correct information or time withrespect to the console 14, and the controlling apparatus 12 may controlinformation or time via the console 14.

For still another example, the exposure switch 15 a may be directlyconnected to the controlling apparatus 12 instead of the operationinterface 15.

Similarly, the systems in the following figures may have variousconfiguration with regard to the connection of the components withoutdeparting from or impairing the object, the functions and the effects ofthe present invention.

Supplementary Techniques

Next, another embodiment of the radiographic imaging system to which thepresent invention is applicable will be described.

The same reference signs are denoted to the same components as those ofthe above-described embodiment, and the description thereof is omitted.

Configuration of Radiographic Imaging System

First, an overview of a radiographic imaging system (hereinafterreferred to as an imaging system 100A) of the present embodiment will bedescribed. FIG. 17 is a block diagram of the imaging system 100A,illustrating the schematic configuration thereof.

As illustrated in FIG. 17 , the imaging system 100A of the presentembodiment includes a tube 13, a console 14 and a clock informationsource apparatus 2, 4 that are the same as those of the previouslydescribed embodiment and further includes a controlling apparatus 12A, aradiographic imaging apparatus (hereinafter referred to as an imagingapparatus 3C) and the like.

The controlling apparatus 12, the console 14 and the imaging apparatus3C can communicate with each other via the clock information sourceapparatus 2, 4.

Details of the controlling apparatus 12 and the imaging apparatus 3Cwill be described later.

FIG. 17 illustrates an example of the imaging system 100A in which bothan irradiating apparatus 1 and the imaging apparatus 3 communicate withthe clock information source apparatus 2, 4 in a wireless manner.However, in the imaging system 100A of the present embodiment, it isonly necessary that at least one of the irradiating apparatus 1 and theimaging apparatus 3 communicates with the clock information sourceapparatus 2, 4 in a wireless manner. For example, as illustrated in FIG.1 , the irradiating apparatus 1 may be connected to the clockinformation source apparatus 2, 4 by wire.

In this configuration, the synchronization accuracy between thecontrolling apparatus 12 and the clock information source apparatus 2, 4can be maintained at a sufficiently high level. Since it is notnecessary to add a function of switching the operation mode to thecontrolling apparatus 12, the controlling apparatus 12 can be producedat low cost.

An IF of the imaging apparatus 3C may be changed from wirelesscommunication to wired communication, and the clock information sourceapparatus 2, 4 may be connected to the imaging apparatus 3C by adedicated line.

In this configuration, it is not necessary to add a function ofswitching the operation mode to the imaging apparatus 3C.

Configuration of Radiographic Imaging Apparatus

Next, the specific configuration of the imaging apparatus 3C of theimaging system 100A will be described. FIG. 18 is a block diagram of theimaging apparatus 3C, illustrating the specific configuration thereof.

The imaging apparatus 3C has a similar configuration as the imagingapparatus 3A of the previously described embodiment. That is, asillustrated in FIG. 18 , the imaging apparatus 3C includes a radiationdetector 32, a scanner driver 33, a reader 34, a storage 35, acommunicator 36, a battery 38 and an imager clock 37A that are the sameas those of the previously described embodiment and further includes animaging controller 31A and a second imager clock 39C.

The second imager clock 39C, which performs a clocking operation in thesame manner as the imager clock 37A, starts the clocking operation togenerate clock information when the apparatus is powered on or itreceives a predetermined external control signal.

The second imager clock 39C may output either timing information such aspulses at regular intervals or time information such as year, month,day, hour, minute and second or the number of counts that is counted upat regular intervals from a certain time point.

In recent years, some LAN chips have such timer function as a defaultfunction, which is a timing synchronization function (hereinafterreferred to as a TSF) specified in the communication standards of theIEEE 802.11.

This type of a wireless LAN chip can be used as the second imager clock39C.

However, the operation of the imager clock 37A and the second imagerclock 39C of the present embodiment is partly different from theoperation of the imager clock 37 and the second imager clock 39A of thepreviously-described embodiment.

Specifically, in the previously-described embodiment, the imager clock37A of the imaging controller 31 corrects the clock information onlywhen the particular condition is met. In contrast, in the presentembodiment, the imaging controller 31A of the imaging apparatus 3Cupdates clock information of the imager clock 37 to first clockinformation every time it receives the first clock information from theclock information source apparatus 2, 4.

Further, the second imager clock 39C of the imaging controller 31 of thepreviously-described embodiment only resets the clock information everytime it receives the first clock information. In contrast, the secondimager clock 39C of the present embodiment can switch its own operationmode to a synchronization mode or to a free-running mode in someconditions.

The switching of the operation mode will be described later.

The imaging controller 31A updates the clock information of the secondimager clock 39C to the clock information of the imager clock 37A atpredetermined timing and then allows the second imager clock 39C tocontinue the counting operation. As described above, the imager clock37A performs time synchronization with the clock information sourceapparatus 2, 4 every time it receives the first clock information fromthe clock information source apparatus 2, 4. Accordingly, the secondimager clock 39C is also repeatedly synchronized with the clockinformation source apparatus 2, 4 at predetermined intervals while it isin the synchronization mode.

When the second imager clock 39C is in the free-running mode, theimaging controller 31A does not update the clock information of thesecond imager clock 39C to the clock information of the imager clock 37Abut allows the second imager clock 39C to continue its countingoperation.

The communicator 36 has the same configuration as that of thepreviously-described embodiment.

Configuration of Radiation Controlling Apparatus

Next, the specific configuration of the controlling apparatus 12A of theimaging system 100A will be described. FIG. 19 is a block diagram of thecontrolling apparatus 12A, illustrating the specific configurationthereof.

As illustrated in FIG. 19 , the controlling apparatus 12A of the presentembodiment includes a radiation controller 121, a high voltage generator122, a storage 123, a communicator 124, an irradiator clock 125 that arethe same as those of the previously-described embodiment and furtherincludes a second irradiator clock 126, a display 127, an operationinterface 15 and the like.

As with the previously-described embodiment (as illustrated in FIG. 1 ),the operation interface 15 may be configured as an operating panel 15separately from the controlling apparatus 12A.

The second irradiator clock 126, which performs a clocking operation inthe same manner as the irradiator clock 125, starts the clockingoperation to generate clock information when the apparatus is powered onor it receives a predetermined external control signal.

The second irradiator clock 126 may output either timing informationsuch as pulses at regular intervals or time information such as year,month, day, hour, minute and second or the number of counts that iscounted up at regular intervals from a certain time point.

In recent years, some LAN chips have such timer function as a defaultfunction, which is a timing synchronization function (hereinafterreferred to as a TSF) specified in the communication standards of theIEEE 802.11.

This type of a wireless LAN chip can be used as the second imager clock125.

The display 127 is constituted by a monitor such as an LCD (LiquidCrystal Display) or a CRT (Cathode Ray Tube). According to a displaysignal from the radiation controller 121, the display 127 displays aninput on the operation interface 15, irradiation result information(e.g. the tube voltage, the tube current, the irradiation time, the tubecurrent-irradiation time product, the number of images taken, thereceived dose, the area dose and the like), a radiographic image basedon image data, and the like.

The operation interface 15 includes a two-button exposure switch 12 h.

The exposure switch 12 h is connected to a main body of the operatingpanel 15 by wire.

However, the exposure switch 12 h may be connected to the main body ofthe operation interface 15 in a wireless manner.

In response to a user operation on the exposure switch 12 h, theoperation interface sends an imaging start signal to the tube 13 and theimaging apparatus 3.

The radiation controller 121 having the above-described configurationupdates the clock information of the irradiator clock 125 to the firstclock information every time it receives the first clock informationfrom the clock information source apparatus 2, 4.

Further, the radiation controller 121 can switch the operation mode ofthe second irradiator clock 126 to the synchronization mode or to thefree-running mode in some conditions.

The switching of the operation mode will be described later.

The radiation controller 121 updates the clock information of the secondirradiator clock 126 to the clock information of the irradiator clock125 at the predetermined timing and then allows the second irradiatorclock 126 to continue its counting operation. As described above, theirradiator clock 125 performs the time synchronization with the clockinformation source apparatus 2, 4 every time it receives the first clockinformation from the clock information source apparatus 2, 4.Accordingly, the second irradiator clock 126 is repeatedly synchronizedwith the clock information source apparatus 2, 4 at predeterminedintervals while it is in the synchronization mode.

While the second irradiator clock 126 is in the synchronization mode,the irradiation controller 121 does not update the clock information ofthe second irradiator clock 126 to the clock information of theirradiator clock 125 but allows the second irradiator clock 126 tocontinue its counting operation.

Mode Switching

Next, the switching of the operation mode of the second irradiator clock126 and the second imager clock 39A will be described in detail, whichis performed respectively by the radiation controller 121 and theimaging controller 31C (hereinafter also referred to as controllers 121,31A).

For example, the clock information source apparatus 2, 4 have a troubleto erroneously reset the first clock information of the clockinformation source apparatus 2, 4. Then, the clock information of theimager clock 37A and the irradiator clock 125 (hereinafter also referredto as clocks 37A, 125), which are synchronized with the clockinformation source apparatus 2, 4, and the second imager clock 39C andthe second irradiator clock 126 (hereinafter also referred to as secondclocks 39C, 126), which correct their own clock information based on theclock information of the clocks 37A, 125, are erroneously updatedaccordingly. When such an abnormality occurs in the course of a serialimaging process which repeats irradiation and accumulation of chargesmultiple times, the image immediately after the update of the clockinformation is taken at different timing.

In order that the imaging cycle is not disrupted in the course of theserial imaging process even in such cases, the controllers 121, 31A ofthe present embodiment switch the operation mode of the secondirradiator clock 126 and the second imager clock 39C according to need.

The controllers 121, 31A make a determination as to whether apredetermined condition is met.

In the present embodiment, the predetermined condition being met refersto an abnormality that can negatively affect the timing of taking imagesbeing detected. Specifically, for example, it is determined that thepredetermined condition is met when: a predetermined event is detectedduring an imaging period; a period of time after the lastsynchronization until the next synchronization (an interval of receivingthe first clock information) exceeds a predetermined threshold during animaging period; the change of the clock information of the second imagerclock 39C and the second irradiator clock 126 by synchronization exceedsa predetermined threshold during an imaging period; the clockinformation is drastically changed by restart of the clock informationsource apparatus 2, 4 or the like during an imaging period; the firstclock information has not been received for a long time during animaging period; or the like.

In addition, it can be determined that the predetermined condition ismet when a certain event such as the following events (1) to (3) occur.The certain event may be one of the following events (1) to (3) or acombination thereof.

(1) The number of receptions of the first clock information in animaging period is counted, and the counted number of receptions is lessthan a predetermined threshold.

(2) The reception interval of the first clock information is repeatedlymeasured during an imaging period, and at least one of the measuredreception intervals of the first clock information is greater than apredetermined threshold.

(3) The amount of change of the clock information of the second imagerclock 39C and the second irradiator clock 126 by synchronization isrepeatedly measured during an imaging period, and at least one of themeasured amounts of change is greater than a predetermined threshold.

In particular, by using the events (2) and (3), it is possible toimmediately detect a failure of synchronization.

When the controllers 121, 31A determine that the predetermined conditionis met, they switch the operation mode of the second irradiator clock126 and the second imager clock 39C to the free-running mode.

After the power is turned on, the controllers 121, 31A keep theoperation mode in the synchronization mode until they determine that thepredetermined condition is met, i.e. during a default state.

When the predetermined condition is no longer met after an image istaken in the free-running mode, the controllers 121, 31A switch(returns) the operation mode to the synchronization mode.

Not only when the predetermined condition is met, the controllers 121,31A may keep the operation mode in the free-running mode while there isa possibility that the predetermined condition will be met.

For example, the controllers 121, 31A may keep the operation mode in thefree-running mode from start to finish of an imaging process asillustrated in FIG. 20 .

Examples of imaging start triggers that start an imaging process includethe following events of Start-1 to Start-8. The imaging start triggermay be a combination of the following events.

Start-1: A user input of an instruction is received on a user interface(hereinafter referred to as a UI) such as the console 14, the imagingapparatus 3, the controlling apparatus 12, the operation interface 15 orthe exposure switch 15 a.

Start-2: An imaging order is selected on the console 14.

Start-3: The imaging apparatus 3 has become ready for receivingradiation.

Start-4: The first button of the exposure switch 15 a is pressed down.

Start-5: The controlling apparatus 12 receives from the tube 13 a signalrepresenting the tube 13 is ready for irradiation, or the controller 121receives from the high voltage generator 122 a signal representing thehigh voltage controller 122 is ready for irradiation.

Start-6: The second button of the exposure switch 15 a is pressed down.

Start-7: The controlling apparatus 12 receives from the tube 13 a signalrepresenting it has started irradiation for taking the first frame, orthe controller 121 receives from the high voltage generator 122 a signalrepresenting it has started irradiation for taking the first frame.

Start-8: A predetermined period of time has elapsed since any of theabove-described imaging start trigger events Start-1 to Start-7 occurs.

Examples of imaging end triggers that end an imaging process include thefollowing events of End-1 to End-9. The imaging end trigger may be acombination of the following events.

End-1: A user input of an instruction is received on the UI such as theconsole 14, the imaging apparatus 3, the controlling apparatus 12, theoperation interface 15 or the exposure switch 15 a.

End-2: The controlling apparatus 12 receives from the tube 13 a signalrepresenting it has completed irradiation for taking the last frame, orthe controller 121 receives from the high voltage generator 122 a signalrepresenting it has completed irradiation for taking the last frame.

End-3: The imaging apparatus 3 or the controlling apparatus 12 hasfinished processing the last frame.

End-4: The imaging apparatus 3 has finished reading the last frame.

End-5: The second button of the exposure switch 15 a is released.

End-6: The first button of the exposure switch 15 a is released.

End-7: An error occurs so that the imaging process can be no longercontinued.

End-8: The next imaging order is selected on the console 14.

End-9: A predetermined period of time has elapsed since any of theabove-described imaging end trigger events End-1 to End-8 occurs.

In a short-time serial imaging process or a still imaging process, evenwhen the operation mode is switched to the free-running mode during theimaging period before the predetermined condition is met, the time lagbetween exposure and accumulation due to the frequency error of theoscillator of the imaging apparatus 3 or the controlling apparatus 12may sometimes fall within a required accuracy. When the imaging system100 is intended only for only short-time serial imaging or stillimaging, this allows simplifying the operation of the controller 121, 31and thereby reducing the time and cost to develop the imaging system100.

However, the shorter the period of time of the free-running mode, thesmaller the operation lag between the imaging apparatus 3 and thecontrolling apparatus 12. Therefore, it is preferred that the operationmode is switched to the free-running mode at a time point as close aspossible to the start of irradiation. For example, when theabove-described event Start-4 that the first button of the exposureswitch is pressed down is selected as the imaging start trigger to startan imaging process, the period of time of the free-running mode islonger as it takes more time for the user to press down the secondbutton after he/she presses down the first button. To avoid this, it ispreferred to select the above-described Start-5 to Start-7 as thetrigger than Start-4.

However, depending on the configuration of the tube 13 and the highvoltage generator 122 and the system configuration, modification of theapparatuses or wiring is required to use a preferred event as theimaging start trigger. In terms of reducing the development cost, it isdesired that the imaging start trigger is selected according to theapparatuses and the system configuration.

When the period of time of the free-running mode is long due to alimited selection of the imaging start trigger events, Start-8 can beselected as the imaging start trigger in order to bring the timing ofswitching the operation mode to the free-running mode closer to thestart of irradiation.

The user may be allowed to switch the operation mode as in Start-1 andEnd-1. When the user knows that the poor radio wave condition due to theposition of the imaging apparatus 3 or radio wave interference withother devices can deteriorate the accuracy of synchronization with thereference time, he/she can manually switch the operation mode to avoiddeterioration of the synchronization accuracy.

In this configuration, the current operation mode may be displayed onthe display 127, the console 14, the operation interface 15 or a display(not shown) of the imaging apparatus 3. This can improve the usabilityof the system 100 and avoid an unnecessary switching operation by theuser.

When the imaging system 100 includes two or more clock informationsource apparatuses 2, 4, the imaging system 100 may be configured toswitch the connection from the current clock information sourceapparatus 2, 4 (n) to another clock information source apparatus 2, 4(n+1) (i.e. to perform wireless LAN loaming) when the imaging apparatus3 and the controlling apparatus 12 are moved so that the connectingcondition with another clock information source apparatus 2, 4 becomesbetter that the connecting condition with the current clock informationsource apparatus 2, 4. In this configuration, when the system 100switches the connection during an imaging period, the reference time ischanged. This may cause loss of synchronization between exposure andreading and result in an imaging failure. To avoid this, the operationmode may be switched to the free-running mode when the connection of theclock information source apparatus 2, 4 is changed during an imagingperiod. The operation mode is then returned to the synchronization modeafter the imaging process ends.

The above-described imaging system 100 is an example in which both thecontrolling apparatus 12 and the imaging apparatus 3 have the functionof switching the operation mode. However, it is only necessary that atleast one of the controlling apparatus 12 and the imaging apparatus 3has the function.

Flow of Serial Imaging

Next, the flow of a serial imaging process in the imaging system 100 ofthe embodiment that can switch the operation mode as described abovewill be described. FIG. 7 is a timing chart illustrating the operationof the imaging system 100 of the embodiment.

The imaging conditions in the illustrated example is as follows. Theconnection to the imaging apparatus 3 is wireless, the imaging mode is aserial imaging mode, and the frame rate is 15 fps. The flow is the sameregardless of the imaging conditions.

In response to a user input of selecting the imaging conditions on theconsole 14, the console 14 sends the above-described imaging conditionsto the imaging apparatus 3 via a wired communication network, the clockinformation source apparatus 2, 4 and wireless communication. Theconsole 14 also sends the imaging conditions and irradiating conditions(a tube current, a tube voltage and an irradiation time) to thecontrolling apparatus 12. As used herein, the irradiation time refers tothe irradiation time of each pulse of a pulsed irradiation.

When the imaging apparatus 3 and the controlling apparatus 12 receivethe imaging conditions and the irradiating conditions, they store thereceived conditions in the respective storage 35, 123 and start aprocess of wireless serial imaging.

Step 1

Then, the controlling apparatus 12 sets up the high voltage generator122 with the received irradiating conditions via the controller 121. Thesystem may be configured such that the user can input irradiatingconditions on the operation interface 15. In this configuration, thecontrolling apparatus 12 sets up the high voltage generator 122 with theirradiating conditions input on the operation interface 15 via thecontroller 121. Until the first or second button of the exposure switch15 a is pressed down, the controlling apparatus 12 sets up the highvoltage generator 122 via the controller 121 every time it receives newirradiating conditions from the console 14. This also applies to thesystem configuration in which the user can input irradiating conditionson the operation interface 15. Since the irradiating conditions arenormally finely adjusted according to the body type of a patient, thisconfiguration can improve the flexibility of the operation sequence andthe usability of the system.

Step 2

Then, the imaging controller 31 and the radiation controller 121 setsthe operation mode of the respective second clocks 39, 126 to thesynchronization mode.

Step 3

The clock information source apparatus 2, 4 sends the first clockinformation to the imaging apparatus 3 and the controlling apparatus 12periodically (normally every 100 ms). Specifically, the first clockinformation sent from the clock information source apparatus 2, 4 to theimaging apparatus 3 and the controlling apparatus 12 represents time ortiming at the time of the sending.

When wireless communication is established between the clock informationsource apparatus 2, 4, and the imaging apparatus 3 and the controllingapparatus 12, the imaging apparatus 3 and the controlling apparatus 12receive the first clock information from the clock information sourceapparatus 2, 4 to update their own respective clocks 37, 125 and thenallow them to continue the counting operation.

Step 4

The imaging apparatus 3 and the controlling apparatus 12 constantlymakes a determination as to whether the predetermined condition is met,i.e. whether their own respective clocks 37, 125 are in synchronizationwith the clock information source apparatus 2, 4 with required accuracy.The determination of the synchronization is made previously because whenthe synchronization accuracy is deteriorated during an imaging period, atime lag occurs between emission of radiation and reading of image datato cause an imaging failure.

Step 5

The imaging apparatus 3 and the controlling apparatus 12 share theirrespective determination results by sending them to each other. Thisallows the imaging apparatus 3 and the controlling apparatus 12 todetect the occurrence of an abnormality immediately, for example, whenthe first clock information has not been received from the clockinformation source apparatus 2, 4 for a long time, or when the firstclock information of the clock information source apparatus 2, 4 islargely changed due to restart of the clock information source apparatus2, 4 or the like.

Step 6

When the controller 121 of the controlling apparatus 12 detects a useroperation of pressing down the second button of the exposure switch 15 a(the controlling apparatus 12 receives the imaging start signal), itsends a corresponding signal to the high voltage generator 122 andshifts into a stand-by state to wait for the ready signal from the highvoltage generator 122, representing the high voltage generator 122 isready for irradiation.

When the high voltage generator 122 receives the imaging start signal,it starts preparation for irradiation. Specifically, the high voltagegenerator 122 prepares a voltage and a current to be output to the tube13 and instructs the tube 13 to start rotation of a rotating anode.

When the rotation of the rotating anode reaches a predetermined speed,the tube 13 sends the ready signal to the high voltage generator 122.When the high voltage generator 122 has become ready for irradiation, itsends to the controller 121 a ready signal representing the high voltagegenerator 122 is ready for irradiation.

When the controller 121 receives the irradiation-ready signal, it sendsto the imaging apparatus 3 via the communicator 124 a commandrepresenting the irradiating apparatus 1 is ready for irradiation.

Step 7

When the imaging apparatus 3 receives the command, it shifts into animaging-ready state.

Then, the imaging apparatus 3 and the controlling apparatus 12 wait forthe second clocks 39, 126 to update their own clock information to theclock information of the clocks 37, 125.

If the update of the clock information is not completed in apredetermined time, the console 14 may be informed of failure of thesynchronization. The console 14 may then display a message or the likeon a display (not shown) to inform the failure of the synchronization,to prompt the user to perform troubleshooting such as restart of theclock information source apparatus 2, 4 and checking the networkconfiguration, or to recommend using a wired connection to take animage. This can speed up recovery from an abnormality.

When the update of the clock information of the second clocks 39, 126 iscompleted, the imaging apparatus 3 calculates an imaging sequence starttime by adding an imaging sequence waiting time stored in the storage 35to the clock information of the second clock 39 at the time of thecompletion. The imaging apparatus 3 stores the calculated imagingsequence start time in the storage 35 and sends it to the controllingapparatus 12.

The imaging sequence waiting time is predefined based on the expecteddelay time of the communication. Specifically, the imaging sequencewaiting time is set to a time length of longer than the maximum probabledelay time. This can prevent an imaging failure that occurs when thecontrolling apparatus 12 receives the imaging sequence start time afterthe time point specified by the imaging sequence start time due to adelay in sending the imaging sequence start time.

In the embodiment, the imaging apparatus 3 sends the imaging sequencestart time to the controlling apparatus 12. Instead, the controllingapparatus 12 may calculates the imaging sequence start time by adding animaging sequence waiting time stored in the storage 123 to the clockinformation of the second clock 126 at the time of completion of theupdate. In this case, the controlling apparatus 12 stores the calculatedimaging sequence start time in the storage 126 and sends it to theimaging apparatus 3.

Step 8

Even after the synchronization with each other is completed, the imagingapparatus 3 and the controlling apparatus 12 continue to make adetermination as to whether they are in synchronization with each other.

After the irradiation-ready signal is sent from the high voltagegenerator 122 to the controller 121, the imaging apparatus 3 and thecontrolling apparatus 12 may sometimes detect a failure of thesynchronization in the period of time after the completion of thesynchronization between the imaging apparatus 3 and the controllingapparatus 12 until the start of reading the last frame of the serialimaging process. In this case, the imaging apparatus 3 and thecontrolling apparatus 12 operate the second clocks 39, 126 in thefree-running mode in the period of time after the detection until thestart of reading the last frame of the serial imaging process, and thenreturns the operation mode to the synchronization mode. When the imagingapparatus 3 and the controlling apparatus 12 detects a failure of thesynchronization, they switch the operation mode to the free-running modebefore updating the clock information of the second clocks 39, 126 tothe clock information of the clocks 37, 125. This can prevent the clockinformation of the second clocks 39, 126 from being set to an abnormalvalue.

Step 9

The controlling apparatus 12 which receives the imaging sequence starttime from the imaging apparatus 3 stores it in the storage 123. Then,the controlling apparatus 12 generates exposure start times of therespective frames from the stored imaging sequence start time and theframe rate (e.g. 15 fps).

Specifically, the exposure start times are generated as follows. Forexample, the exposure start time of the first frame is set to the sametime as the imaging sequence start time, and the imaging cycle time(=1/frame rate) is cumulatively added thereto to obtain the exposurestart times of the second and later frames. That is, the exposure starttime of the N-th frame=the imaging sequence start time÷(frame numberN−1)×the imaging cycle time.

The exposure start times may be generated beforehand and stored in thestorage 123 so that they can be referenced every time an instruction tostart exposure for each frame is received. Alternatively, the exposurestart times may be generated one by one by adding the imaging cycle timeto the exposure start time of a previous frame every time an instructionto start exposure for each frame is received. The latter configurationallows reduction of the capacity of the storage 123 and facilitatesadapting the system when the number of frames in each imaging processvaries.

Step 10

The controller 121 sends to the high voltage generator 122 a signalrepresenting an instruction to start exposure for each frame image everytime the clock information of the second irradiator clock 126 reachesany one of the exposure start times of the respective frame images.

The high voltage generator 122 controls the tube 13 to emit theradiation R for a preset irradiation time every time it receives thesignal representing the instruction to start exposure. That is, thecontrolling apparatus 12 controls the tube 13 to emit the radiation Rwhen the clock information of the second irradiator clock 126 reaches afirst predetermined value.

Step 11

When the controller 121 detects the occurrence of an event indicatingthe end of the imaging process, e.g. the second button of the exposureswitch 15 a is released, the number of frame images taken reaches themaximum frame number stored in the storage 123, or the controller 121receives a shut-down notification from the high voltage generator 122 orthe imaging apparatus 3, it sends a command to notify the completion ofthe imaging process to the imaging apparatus 3 via the communicator 124and does not send any further instruction to start exposure to the highvoltage generator 122 during the current imaging process. That is, theimaging process ends.

The maximum frame number may be a fixed value stored in the storage 123.Alternatively, the maximum frame number may be a value that is input onthe console 14 by the user, which is sent to the controlling apparatus12 and stored in the storage 123.

Step 12

The imaging apparatus 3 generates reading start times of the respectiveframes based on the imaging sequence start time stored in the storage123, the frame rate and the accumulation time of each frame.

In order to avoid exposure in a reading step, the accumulation time islonger than the irradiation time of each frame.

Specifically, the reading start times are generated as follows. Forexample, the reading start time of the first frame is set to the imagingsequence start time+the accumulation time of each frame, and the imagingcycle time (=1/frame rate) is cumulatively added thereto to calculatethe reading start times of the second and later frames. That is, thereading start time of the N-th frame=the imaging sequence start time+theaccumulation time of each frame+(frame number N−1)×the imaging cycletime.

The reading start times may be generated beforehand and stored in thestorage 123 so that they can be referenced every time a frame is read.Alternatively, the reading start times may be generated one by one byadding the imaging cycle time to the reading start time of a previousframe every time a frame is read. The latter configuration allowsreduction of the capacity of the storage 123 and facilitates adaptingthe system when the number of frames in each imaging process varies.

As described above, the imaging apparatus 3 generates the reading starttimes from the imaging sequence start time and the frame rate by itselfwhile the controlling apparatus 12 generates the exposure start timessimilarly by itself. That is, the imaging sequence start time and theframe rate are only information that has to be shared between theimaging apparatus 3 and the controlling apparatus 12. This can reducethe risk of an imaging failure caused by communication delay between theimaging apparatus 3 and the controlling apparatus 12 due to a packetloss or the like. Such an imaging failure occurs when a reading starttime is received after the time point specified by the reading starttime, or when an exposure start time is received after the time pointspecified by the exposure start time.

Step 13

The imaging apparatus 3 starts reading charges accumulated in theradiation detector 32 to generate image data of a frame image every timethe clock information of the second imager clock 39 reaches any one ofthe reading start times of the respective frames. That is, the imagingapparatus 3 reads image data of a radiographic image from the chargesgenerated in the radiation detector 32 when the clock information of thesecond imager clock 39 reaches a second predetermined value.

Step 14

Then, the imaging apparatus 3 terminates the imaging process when itdetects the occurrence of an event indicating the end of the imagingprocess, e.g. the imaging apparatus 3 receives a command to notify thecompletion of the imaging process from the controlling apparatus 12, orthe number of frame images taken reaches the maximum frame number storedin the storage 35.

When the imaging apparatus 3 detects the occurrence of an eventindicating the end of imaging process during a reading step, itpreferably terminates the imaging process after completion of thereading step. This can prevent an abnormality that the frame image ofthe last frame is partly missing.

The above-described supplementary techniques include the followingtechniques.

1. A radiographic imaging system, comprising:

a reference time apparatus comprising: a first clock which keeps time;

a second clock and a third clock which respectively keep time;

a radiographic controlling apparatus which emits radiation from aradiation tube when a clock value of the second clock reaches a firstpredetermined value; and

a radiographic imaging apparatus comprising: a radiation detector whichgenerates charges when receiving radiation; and a reader which readsimage data of a radiographic image based on the charges generated by theradiation detector when a clock value of the third clock reaches asecond predetermined value,

wherein the second clock and the third clock are capable of changing anown operation mode to a synchronization mode to perform synchronizationto the first clock at predetermined timing, and

wherein at least one of the second clock and the third clock

-   -   makes a determination as to whether a predetermined condition is        satisfied, and    -   in response to determining that the predetermined condition is        satisfied, switches the operation mode to a free-running mode to        keep time without performing the synchronization to the first        clock.

2. The radiographic imaging system according to claim 1, wherein atleast one of the second clock and the third clock determines that thepredetermined condition is satisfied when a predetermined event isdetected during an imaging process.

3. The radiographic imaging system according to claim 2,

wherein while the second clock and the third clock operate in thesynchronization mode, the second clock and the third clock repeatedlyperform synchronization to the first clock at predetermined intervals,and

wherein at least one of the second clock and the third clock determinesthat the predetermined condition is satisfied when a length of time froma previous synchronization to a current synchronization exceeds each ofthe predetermined intervals.

4. The radiographic imaging system according to claim 2, wherein atleast one of the second clock and the third clock determines that thepredetermined condition is satisfied when an amount of change of a countvalue of said at least one of the second clock or the third clock bysynchronization exceeds a predetermined threshold during an imagingprocess.

5. The radiographic imaging system according to claim 1, wherein atleast one of the second clock and the third clock which operates in thefree-running mode in an imaging process switches the own operation modeto the synchronization mode when the imaging process ends.

6. The radiographic imaging system according to claim 1, wherein theradiation controlling apparatus or the radiographic imaging apparatuswhich makes the determination as to whether the predetermined conditionis satisfied and which switches the operation mode comprises acommunicator which is capable of communicating with the reference timeapparatus in a wireless manner.

7. The radiographic imaging system according to claim 6,

wherein the communicator communicates with the reference time apparatusin a wireless manner according to an IEEE 802.11 standard, and

wherein the second clock or the third clock which is provided in anapparatus comprising the communicator performs synchronization to thefirst clock by using a time synchronization function specified in thestandard when the second clock or the third clock operates in thesynchronization mode.

The above-described techniques can be used to stably perform a wirelessserial imaging process.

EXAMPLES

Next, problems that can occur in the imaging systems 100, 100A, 100B ofthe above-described embodiments and specific examples for solving theproblems will be described.

Example 1-1

The console 14 monitors the overall control of the imaging system 100,i.e. the operational state (which indicates whether a device is in anormal state or an abnormal state, whether a device is in a runningstate or a shutdown state, and the like) of the devices of the imagingsystem 100 or a device that mediates sending and receiving informationto and from another system other than the imaging system 100. Further,the console 14 synchronizes the devices of the imaging system 100 andthe device that mediates sending and receiving information to and fromanother system other than the imaging system 100. However, in theabove-described embodiments, the clock information source apparatus 2, 4is not connected to the console 14 but to the controlling apparatus 12.Accordingly, the console 14 has to perform processing such assynchronization check via the controlling apparatus 12, which results inthe low efficiency of the processing.

To cope with the problem, for example, the clock information sourceapparatus 2, 4 may be connected to the console 14 as illustrated in FIG.22 . Since the clock information source apparatus 2, 4 is directlyconnected to the console 14, the console 14 can perform processing suchas synchronization check with high efficiency.

While the clock information source apparatus 2, 4 is connected to theconsole 14, the clock information source apparatus 2, 4 may also beconnected to the controlling apparatus 12. In this configuration, notonly the console 14 but also the controlling apparatus 12 can besynchronized with the clock information source apparatus 2, 4. That is,the controlling apparatus 12 and the console 14 can individually besynchronized with the imaging apparatus 3.

Further, in this configuration, it may be checked as to whether there isa time lag between the operation of the controlling apparatus 12 and theoperation of the console 14. When the synchronization cannot beperformed between the clock information source apparatus 2, 4 and thecontrolling apparatus 12 or between the clock information sourceapparatus 2, 4 and the console 14 due to a communication failure or thelike, the time lag between the operation of the controlling apparatus 12and the operation of the console 14 is gradually increased. By detectingthe time lag, it is possible to suspend the imaging process or todisplay a warning message.

Example 1-2

In the above-described embodiments, when the clock information sourceapparatus 2, 4 is connected to the controlling apparatus 12 or theconsole 14 in a wired manner, it is necessary to use a dedicated linesince it is also necessary in order to synchronize them with each other.

To cope with the problem, in the above-described embodiments, the clockinformation source apparatus 2, 4 may be connected to the imagingapparatus 3 in a wireless manner, and the clock information sourceapparatus 2, 4 may also be connected to the controlling apparatus 12 ina wireless manner as illustrated in FIG. 23 .

In this regard, the TSF specified in the communication standard IEEE802.11 may be used to update the clock information of imager clock 37 ofthe imaging apparatus 3 to the clock information of the clockinformation source apparatus 2, 4 so as to perform synchronization ofthe clock information.

In this configuration, the same clock information can be used forsynchronization between the clock information source apparatus 2, 4 andthe imaging apparatus 3 and synchronization between the clockinformation source apparatus 2, 4 and the controlling apparatus 12. As aresult, it is possible to perform the time synchronization withoutlaying a cable around the subject S. Further, the same first clockinformation is used to update the clock information. This can reduce theoperation lag between the controlling apparatus 12 and the imagingapparatus 3 and eliminate the necessity of an additional component forcompensating asynchronization with other apparatuses. Further, the sameradio wave is used to update the clock information. This can reduce theoperation lag.

Instead between the clock information source apparatus 2, 4 and thecontrolling apparatus 12, the clock information source apparatus 2, 4may be connected to the console 14 in a wireless manner for thesynchronization.

Alternatively, the clock information source apparatus 2, 4 may beconnected to the controlling apparatus 12 in a wireless manner while theclock information source apparatus 2, 4 may also be connected to theconsole 14 in wireless manner for the synchronization.

Example 1-3

In the above-described embodiments, the clock information sourceapparatus 2, 4 may be directly connected to the controlling apparatus12. A problem in this configuration is that the arrangement of the clockinformation source apparatus 2, 4, the controlling apparatus 12 and thecable connecting them is sometimes limited.

Further, when the clock information source apparatus 2, 4 is directlyconnected to the controlling apparatus 12, the long distance of thewired connection may increase the occurrence of a communication failurebetween the clock information source apparatus 2, 4 and the controllingapparatus 12.

To cope with the problem, in the above-described embodiments, theradiation controlling apparatus may be connected to the clockinformation source apparatus 2, 4 via a network device 5 as illustratedin FIG. 24 . For example, the network device 5 may be constituted by ahub.

In this regard, it is preferred to use a low-latency dedicated line forthe connection between the clock information source apparatus 2, 4 andthe network device 5 and between the network device 5 and thecontrolling apparatus 12, and to use the time synchronization of wiredcommunication specified in IEEE 1588 for the synchronization betweenthem.

This can reduce the limitation of the arrangement of the clockinformation source apparatus 2, 4, the controlling apparatus 12 and thecable.

Further, the connection via the network device 5 allows long-distancewired connection without intervention of any other device between theapparatuses. This can prevent degradation of communication signals andimprove the reliability of the communication.

Example 1-4

In the above-described embodiments, the synchronization may be performedbased on the clock information by using an external signal. A problem inthis configuration is that it is impossible to make a determination asto whether the imaging apparatus 3 is in synchronization. Specifically,once wireless communication is lost due to radio wave interference orthe like, the imaging apparatus 3 cannot inform the controllingapparatus 12 of the possibility of asynchronization in order to stopirradiation.

To cope with the problem, in the above-described embodiments, the clockinformation source apparatus 2, 4 may be incorporated in the imagingapparatus 3, and the imaging apparatus 3 sends the first clockinformation to the controlling apparatus 12 for the synchronization asillustrated in FIG. 25 .

Further, it is preferred that the controlling apparatus 12 includes aclock and performs the synchronization.

In this configuration, when the synchronization has not been performedfor a certain period of time, the controlling apparatus 12 canunderstand the possible occurrence of an operation lag. Therefore, thecontrolling apparatus 12 can stop irradiation even when it cannotcommunicate with the imaging apparatus 3 in a wireless manner.

Further, it is not necessary to provide the intervening clockinformation source apparatus 2, 4. This can reduce the risk ofcommunication delay due to a trouble of the clock information sourceapparatus 2, 4.

Example 1-5

In the above-described embodiments, the radiographic apparatus 12 maynot support wireless communication. A problem in this configuration isthat the time synchronization cannot be performed in wireless manner.

To cope with the problem, in the above-described embodiments, acommunication module 16 that can receive a radio wave from the clockinformation source apparatus 2, 4 may be connected to the controllingapparatus 12 as illustrated in FIG. 26 . Then, the controlling apparatus12 can receive the reference time from the clock information sourceapparatus 2, 4 via the communication module 16.

It is preferred to use a low-latency dedicated line for the connectionbetween the communication module 16 and the controlling apparatus 12 andto use the time synchronization of wired communication specified in IEEE1588.

This configuration enables wireless time synchronization even when theradiation controlling apparatus does not support wireless communication.

The communication module 16 only receives signals, and no radio signalis output from the communication module 16 or the irradiating apparatus1. This can reduce the occurrence of a trouble relating to output ofradio signals.

When it is not necessary to consider problems related to output of radiosignals from the communication module 16 or the irradiating apparatus 1,the communication module can have a transmission function.

Example 1-6

In the above-described embodiments, when the user wants to compare astill image or a dynamic image obtained by the system with a measurementresult or an output image obtained by an external apparatus, it isnecessary to synchronize the imaging system 100 with the externalapparatus in order to confirm that they are taken at the same timing.For example, when an image is taken in synchronization with heartbeats,it is necessary to take an image at the same timing of heartbeats, toextract an image taken at a certain time point in a heartbeat fromserial images or to link serial images to heartbeat data. Accordingly,it is necessary to synchronize the time.

To achieve this, in the present embodiments, the imaging system 100 maybe connected to an external apparatus 6 by the same communicator as thatbetween the clock information source apparatus 2, 4 and the controllingapparatus 12 or the imaging apparatus 3 as illustrated in FIG. 27 , andthe imaging system 100 may be synchronized with the external apparatus 6based on the first clock information of the clock information sourceapparatus 2, 4.

This allows synchronized imaging with the external apparatus 5. Forexample, a heart rate monitor may be connected as the external apparatus5. In this case, it is possible to take an image in synchronization withheartbeats by suitably controlling, storing and displaying the timing.It is also possible to know the timing of an obtained dynamic image withrespect to heartbeats in order to make a diagnosis.

In addition to a heart rate monitor, a variety of devices may be used asthe external apparatus 5 according to a subject to be radiographed,examples of which include a device for measuring a respiratory statesuch as a spirometer, a displacement sensor and an acceleration sensorfor measuring a movement, and the like.

Any one of the external apparatus 5, the controlling apparatus 12 andthe imaging apparatus 3 or all of them may include a storage for storingclock information.

By storing the clock information, it is possible to organize or extractan image and a measurement result obtained at the same time based on theclock information.

Example 1-7

In the above-described embodiments, the communicators send and receivedata as well as the clock information for the synchronization. Problemsin this configuration are the limited amount or speed of datacommunication, possible delay of data communication, and possible lossof data during communication.

To cope with the problems, in the above-described embodiments, the clockinformation source apparatus 2, 4 may be connected to the controllingapparatus 12 by two or more different communicator as illustrated inFIG. 28 .

For example, the clock information source apparatus 2, 4 may beconnected to the controlling apparatus 12 in a wireless manner to sendand receive the clock information for synchronizing the time of therespective clock in a wireless manner. Furthermore, the clockinformation source apparatus 2, 4 is connected to the controllingapparatus 12 also in a wired manner (e.g. by Ethernet) to send andreceive information other than the clock information for the timesynchronization (e.g. irradiating conditions, irradiation time, etc.)

In this configuration, the communicator for the time synchronization canbe separated from the communicator for sending and receivinginformation. As a result, a delay or loss of information does not occur,and it is possible to send and receive information at the same time withperforming the time synchronization.

Further, it is possible to select suitable communicator respectively forthe time synchronization and the sending and receiving of information.

Example 1-8

In the above-described embodiments, the imaging apparatus 3D may includeanother second imager clock 39D that is different from that in theabove-described embodiments as illustrated in FIG. 29 . For example, thesecond imager clock 39D may use an atomic clock, the GPS, an NTP or thelike. When an atomic clock or the GPS is used, the second imager clock39D may include an antenna for receiving a radio wave.

By comparing the clock information of the imager clock 37 with the clockinformation of the second imager clock 39D at suitable timing, thesystem detects the time difference between the clock information of theimager clock 37 and the second imager clock 39D.

In this configuration, even when the time difference between the firstclock information of the clock information source apparatus 2, 4 and thesecond clock information of the imager clock 37 is gradually increasedafter the communication between the clock information source apparatus2, 4 and the imaging apparatus 3 is lost as illustrated in FIG. 30 , theimaging apparatus 3 can detect the occurrence of a time difference bycomparing the clock information of the imager clock 37 with the clockinformation of the second imager clock 39D.

The imaging apparatus 3 may calculate the time difference (time lag)between the clock information of the respective clocks and make adetermination as to whether the calculated difference is greater than apredetermined value. With this configuration, the imaging apparatus 3can understand whether the accuracy of the time synchronization issufficient. If the time difference is greater than the predeterminedvalue, the system may perform the same output as in the above-describedembodiment, such as giving a notification that the time difference isgreater than the predetermined value, giving a notification that imagingis prohibi, or cancelling the imaging process.

FIG. 30 illustrates an example in which the second imager clock 39D isused to detect the time difference only in a synchronization failureperiod in which the synchronization between the imaging apparatus 3 andthe clock information source apparatus 2, 4 cannot be performed.However, the second imager clock 39D may also be used to detect the timedifference even in a synchronized period in which the synchronizationwith the clock information source apparatus 2, 4 is successfullyperformed.

Example 1-9

In Example 1-8, the imaging controller 31 may update the clockinformation of the imager clock 37 to the clock information of thesecond imager clock 39D or update the clock information of the secondimager clock 39D to the clock information of the imager clock 37.

As illustrated in FIG. 31 , while communication is established betweenthe clock information source apparatus 2, 4 and the imaging apparatus 3,the imaging apparatus 3 periodically update the clock information of theimager clock 37 by using the first clock information of the clockinformation source apparatus 2, 4. When it becomes impossible to performthe synchronization between the clock information source apparatus 2, 4and the imaging apparatus 3, the imaging apparatus 3 periodically updatethe clock information of the imager clock 37 by using the clockinformation of the second imager clock 39D.

That is, even when the communication between the clock informationsource apparatus 2, 4 and the imaging apparatus 3 is lost, the imagingapparatus 3 can continue the time synchronization with the clockinformation source apparatus 2, 4 to continue the imaging process.

FIG. 31 illustrates an example in which the second imager clock 39D isused to update the clock information of the imager clock 37 only whilethe communication between the clock information source apparatus 2, 4and the imaging apparatus 3 is lost. However, the second imager clock39D may also be used to update the clock information of the imager clock37 even while the synchronization with the clock information sourceapparatus 2, 4 is successfully performed.

Example 1-10

In Example 1-8 and Example 1-9, a measuring unit may be provided tomeasure the reliability of communication between the second imager clock39D and the outside.

For example, when the second imager clock 39D uses a radio wave, e.g.uses an atomic clock or the GPS, a device that measures the intensity ofthe radio wave may be provided as the measuring unit.

The imaging controller 31 periodically compares the measurement value ofthe device with a predetermined value. When the measurement value isless than the predetermined value, the imaging controller 31 determinesthat the reliability of the communication is insufficient. Then, theimaging controller 31 performs an output such as giving a notificationto the user that the reliability of the second imager clock 39D is low,giving a notification that imaging is disabled, or cancelling theimaging process.

This can prevent an image from being erroneously taken when thereliability of the communication of the second imager clock 39D is low.The subject S can thus be prevented from being exposed to unnecessaryradiation.

Example 1-11

In the above-described embodiments, the clock information may be updatedonly before the start of an imaging period (before the state changesfrom a stand-by state to an operational state). During the imagingperiod, the clock information may not be updated, but the timedifference (time lag) between the first clock information of the clockinformation source apparatus 2, 4 and the clock information of theimager clock 37 may only be monitored, for example, as illustrated inFIG. 32 .

The difference may be monitored at the timing of the timesynchronization between the clock information source apparatus 2, 4 andthe imaging apparatus 3 (the timing of sending the first clockinformation of the clock information source apparatus 2, 4) or atpredetermined timing of the imager clock 37.

The difference may be monitored at both the timing of the timesynchronization of the clock information source apparatus 2, 4 and thepredetermined timing of the imaging apparatus 3. In this configuration,the time difference can be monitored even when any of the clockinformation source apparatus 2, 4 and the imager clock 37 have atrouble.

When the second imager clock 39D as described in Example 1-9 to Example1-11 is provided, the difference between the clock information of theimager clock 37 and the clock information of the second imager clock 39Dmay be monitored instead. In this configuration, the time difference maybe monitored at predetermined timing of the second imager clock 39D.

Example 1-12

In the above-described embodiments, the communicator 36 or the imagingcontroller 31 of the imaging apparatus 3 may have a monitoring functionof monitoring whether the communication is maintained in a normalcondition.

When the imaging controller 31 or the communicator 36 having themonitoring function detects loss of the communication, it determinesthat the communication is not maintained in a normal condition. Then,the imaging controller 31 or the communicator 36 performs an output suchas giving a notification to the user that the communication is lost,giving a notification that imaging is disabled, or cancelling theimaging process.

This can prevent an image from being erroneously taken when thecommunication is not maintained in a normal condition. The subject S canthus be prevented from being exposed to unnecessary radiation.

Example 2-1

Another problem in the above-described embodiments is that a desiredresult is not obtained and imaging fails when the system starts takingan image without checking whether the apparatuses are in synchronizationwith each other. An imaging failure requires another imaging, and thesubject S is exposed to unnecessary radiation.

To cope with the problem, in the above-described embodiments, the timesynchronization may be checked at the start of taking an image asillustrated in FIG. 33 , e.g. when the user presses down the exposureswitch (Step 1). If the accuracy of the time synchronization is at adesired level or more (Step S1, Yes), imaging is enabled (Step S2) andthe imaging process starts (Step S3). If the accuracy of the timesynchronization is insufficient (Step S1, No), the system takes ameasure such as giving to the user a notification that the apparatusesare out of synchronization, giving a notification that imaging isdisabled, or cancelling the imaging process (Step S4).

It is preferred that whether to give the notification to the user or togive the notification that imaging is disabled is selected according tothe amount of time difference.

This can prevent an image from being erroneously taken when theapparatuses are not in synchronization. The subject S can thus beprevented from being exposed to unnecessary radiation.

Example 2-2

In Example 2-1, the synchronization (Step S1 i) may be performed afterStep S4, and thereafter the processing of Step S1 to Step S4 is repeatedas illustrated in FIG. 34 .

When the synchronization is performed again, a notification may be givenor the imaging process may be canceled.

It is preferred that whether to give the notification to the user or togive the notification that imaging is disabled is selected according tothe amount of time difference.

This can prevent an image from being erroneously taken when theapparatuses are not synchronized. The subject S can thus be preventedfrom being exposed to unnecessary radiation.

Example 2-3

In Example 2-2, the clock information source apparatus 2, 4 may bereconnected to the controlling apparatus 12 and the imaging apparatus 3(Step S21) after the second Step S4, and thereafter the processing ofStep S1 to S4 may be repeated again as illustrated in FIG. 35 .

When the accuracy of the time synchronization is insufficient even afterthe communication is disconnected and then reconnected, it is preferredthat the system takes measures such as giving to the user a notificationthat the apparatuses are not synchronized, giving a notification thatimaging is disabled, or cancelling the imaging process.

It is preferred that the determination as to whether to give thenotification to the user or the determination as to whether to give thenotification that imaging is disabled is made based on the amount oftime difference.

This can prevent an image from being erroneously taken when theapparatuses are not synchronized. The subject S can thus be preventedfrom being exposed to unnecessary radiation.

Example 2-4

In Example 2-3, the clock information source apparatus 2, 4 may berestarted (Step S31) after the third Step S4, and thereafter theprocessing of Step S1 to Step S4 is repeated again as illustrated inFIG. 36 .

When the accuracy of the time synchronization is insufficient even afterthe clock information source apparatus 2, 4 is turned off and is thenrestarted and reconnected, it is preferred that the system takesmeasures such as giving to the user a notification that the apparatusesare not synchronized, giving a notification that imaging is disabled, orcancelling the imaging process.

It is preferred that whether to give the notification to the user or togive the notification that imaging is disabled is selected according tothe amount of time difference.

This can prevent an image from being erroneously taken when theapparatuses are not synchronized. The subject S can thus be preventedfrom being exposed to unnecessary radiation.

Example 2-5

Another problem in the above-described embodiments is that even when theuser wants the system to perform the synchronization at desired timing,there is no way for the user to input the instruction.

To cope with the problem, in the above-described embodiments, theimaging apparatus 3 may be provided with a specific operation button 3 bas illustrated in FIG. 37 . In response to a user operation of pressingdown the operation button 3 b, the system performs the synchronizationprocessing.

In this configuration, the time synchronization between the imagingapparatus 3 and the clock information source apparatus 2, 4 can beperformed at the timing desired by the user.

The system may be configured to perform the time synchronization inresponse to a specific user operation such as holding down the operationbutton 3 b for a long time or pressing the operation button 3 b multipletimes.

In this configuration, another button that is originally installed for adifferent purpose can also be used as the operation button 3 b, and itis not necessary to excessively increase the number of buttons of theimaging apparatus 3.

Example 3-1

Another problem in the above-described embodiments is that the systemcontinues an imaging process even when a large time lag occurs betweenthe operation of the irradiating apparatus 1 and the operation of theimaging apparatus 3. This results in an imaging failure, and the subjectS is exposed to unnecessary radiation.

To cope with the problem, in the above-described embodiments, the systemmay give a notification or cancel the imaging process according to thedifference (the amount of time difference) between the first clockinformation of the clock information source apparatus 2, 4 and thesecond clock information of the imager clock 37 of the imaging apparatus3.

Specifically, the imaging controller 31 or the like may have a functionof comparing the amount of time difference with a predeterminedthreshold. When the time difference exceeds the threshold, the systemdisplays a warning to the user or stops irradiation to cancel theimaging process.

This can prevent an image from being taken when the apparatuses are notsynchronized. The subject S can thus be prevented from being exposed tounnecessary radiation.

Two (higher and lower) thresholds may be set as illustrated in FIG. 38 .When the time difference exceeds the first (lower) threshold, the systemgives a warning. Then, when the time difference exceeds the second(higher) threshold, the system cancels the imaging process.

The system may be configured not to display the warning when the timedifference is greater than the first threshold but is on a decreasingtrend as in the time range (2).

Example 3-2

As described in Example 3-1, there is a problem that the systemcontinues an imaging process even when a large time lag occurs betweenthe operation of the irradiating apparatus 1 and the operation of theimaging apparatus 3 in the above-described embodiments. To cope with theproblem, in Example 3-1, the system gives the notification to the useror cancels the imaging process according to the amount of actual timedifference. Instead, the system may predict a future time difference andgive a notification to the user or cancel imaging process according tothe amount of predicted future time difference.

Specifically, the relationship between the imaging time (the number ofimages taken) in a past imaging process and the difference (the amountof time difference) between the first clock information of the clockinformation source apparatus 2, 4 and the second clock information ofthe imager clock 37 is stored in the storage 31.

The imaging controller 31 has a function of predicting the amount oftime difference when the number of images taken reaches the presetnumber of the current imaging process based on the stored relationshipbetween the imaging time and the amount of time difference in the past,a function of comparing the predicted time difference with apredetermined threshold, and a function of performing an output when itis determined that the predicted amount of time difference is greaterthan the threshold, such as giving a notification that there is apossibility of imaging failure due to loss of synchronization when theimaging process is continued to the last, giving a notification thatimaging is disabled, or cancelling the imaging process.

This can prevent an image from being taken when the apparatuses are notsynchronized and thereby reduce the risk that the subject S is exposedto unnecessary radiation.

As illustrated in FIG. 39 , two (lower and higher) thresholds may beset. When the predicted time difference is greater than the first(lower) threshold but lower than the second (higher) threshold as inCase 1, i.e. it is determined that the time difference does not largelyaffect the imaging process, the system may give a warning. When thepredicted time difference is clearly greater than the second threshold,i.e. the imaging will certainly fail if the imaging process is continuedto the last, the system may give to the radiographer a notification thatthere is a possibility that the time difference will be increased tosuch a level that affects the image by the end of the imaging period orthe system may cancel the imaging process.

Example 3-3

Even when the time difference (time lag) between the first clockinformation of the clock information source apparatus 2, 4 and thesecond clock information of the imager clock 37 is greater than acertain threshold, it is sometimes possible to obtain an image that canbe used for diagnosis. In the above-described embodiments, the systemautomatically cancels the imaging process or gives a notification toprompt the user to cancel the imaging process when the time differenceexceeds the threshold. A problem in this configuration is that once thetime difference exceeds the threshold, the images that have been alreadytaken become useless. As a result, the subject S may be exposed tounnecessary radiation.

To cope with the problem, in the above-described embodiment, the systemmay continue an imaging process until a preset number of images aretaken even when the time difference exceeds a threshold. After thecompletion of the imaging process, the system may give a notificationthat the time difference exceeded a threshold.

Specifically, the imaging controller 31 has a function of comparing thetime difference (time lag) between the first clock information of theclock information source apparatus 2, 4 and the second clock informationof the imager clock 37 with a predetermined threshold.

Further, the imaging controller 31 has the following function. When theimaging controller 31 determines that the time difference has exceededthe threshold, it stores the determination result and notifies it to theuser during or after the imaging period.

In this configuration, it is possible to obtain an image that can beused for diagnosis even when the time difference reaches a certainlevel. This can reduce the risk that the subject S is exposed tounnecessary radiation.

When the time difference exceeds the threshold, the imaging controllermay store the period of time in which the time difference is greaterthan the threshold and associate specific information (flag or the like)with the image data of an image that is taken in the period of time inwhich the time difference is greater than the threshold. When the imagesare checked afterwards, this enables specifying which image was takenwhile the time difference was greater than the threshold.

Two (lower and higher) thresholds may be set as illustrated in FIG. 40 .The imaging controller 31 may store the period of time in which the timedifference is greater than the first (lower) threshold as in Case 1,i.e. the time difference is at a warning level, and the period of timein which the time difference is greater than the second (higher)threshold as in Case 2, i.e. the time difference is at such a high levelthat requires cancelling the imaging process.

Example 4-1

Another problem in the above-described embodiments is that since thealignment between the first clock information of the clock informationsource apparatus 2, 4 and the clock information of the imager clock 37is performed at a moment, the clock information is sometimes changedgreatly by the update to cause a trouble.

For example, when the clock information is changed greatly to passthrough the timing of two or more events, operations such asirradiation, accumulation of charges, reading and transfer are performedat the same time, which causes a trouble such as an imaging failure.

To cope with the problem, in the above-described embodiments, when it isnecessary to update the clock information in an imaging period, theclock information may be aligned and synchronized not at a moment butgradually.

Specifically, every time the first clock information is sent orreceived, the first clock information of the clock information sourceapparatus 2, 4 or the second clock information of the imager clock 37 isupdated such that the time difference (time lag) between them is reducedlittle by little.

For example, the term “little by little” means a predeterminedpercentage (e.g. x %) of the time difference or a predetermined fraction(e.g. a fraction of x) of the time difference as illustrated in FIG. 41.

This configuration can prevent problems related to a large change of theclock information.

However, when the time difference is large, such gradual reduction ofthe time difference may sometimes require a lot of time until the timedifference is reduced to such a level that does not affect outputimages.

To avoid this, the amount of change of the clock information percorrection may be increased according to the amount of time difference.

Example 4-2

Another problem in the above-described embodiments is that since thealignment between the first clock information of the clock informationsource apparatus 2, 4 and the clock information of the imager clock 37is performed at a moment, the clock information is sometimes decreased(the time represented by the clock information goes back) by the updateto cause a trouble.

For example, as illustrated in FIG. 42A, when the clock information isrewound across the time point of a certain event by the update afterpassing the time point of the event, the same event is erroneouslyperformed twice. When the event is irradiation, the subject S is exposedto unnecessarily repeated radiation. Further, the frame that is takenwhen the irradiation is repeated is exposed to the radiation R twice andhas a different image quality than the other frames.

To cope with the problem, in the above-described embodiments, when theoccurrence of a time difference between the clock information of theclocks is detected, the clock rate of at least one of the clocks may beadjusted.

Specifically, when the first clock information is sent or received, theclock information is not updated. Instead, the clock rate of the earlierclock may be decreased or the clock rate of the later clock may beincreased as illustrated in FIG. 42B so that the time difference isreduced to a level that does not require an update of the clockinformation by the time the next first clock information is sent orreceived.

This can prevent problems relating to rewind of the clock information.

Example 4-3

As described in Example 4-2, there is a problem that an update thatrewinds the clock information may sometimes cause repetition of the sameevent. To cope with the problem, in Example 4-2, the clock rate of theclocks is changed. Instead, as illustrated in FIG. 43 , a no eventperiod Td in which execution of the same event is prohibited may be setimmediately after an event is performed.

Without changing the clock rate of the clocks, this can prevent atrouble that the same event is repeated.

Example 5-1

In the above-described embodiments, when the communication between theclock information source apparatus 2, 4 (irradiating apparatus 1) andthe imaging apparatus 3 is lost, an imaging process has to be canceledregardless of whether it is possible to further continue the imagingprocess. This is because it is uncertain how long the imaging processcan be continued.

To cope with the problem, in the above-described embodiments, the numberof images that can be further taken may be calculated from the clockrate and the accuracy of the clock information source apparatus 2, 4 andthe imager clock 37, and the imaging process may be continued until thenumber of images taken reaches the calculated number.

Specifically, the relationship between factors that affect the accuracyof the oscillation cycle of the oscillators of the irradiating apparatus1 and the imaging apparatus 3, and the oscillation cycle is stored inthe storage 35 beforehand.

Further, the imaging controller 31 has a function of predicting thechange of the time difference (time lag) between the first clockinformation of the clock information source apparatus 2, 4 and thesecond clock information of the imager clock 37 based on the timedifference immediately after the loss of the connection, the clock rateof the clock information source apparatus 2, 4 and the imager clock 37and the relationship between the factors and the accuracy stored in thestorage 35. As illustrated in FIG. 44 , the change of the timedifference may have an increasing or decreasing trend depending on theaccuracy.

Further, from the predicted change of the time difference, the imagingcontroller 31 has a function of calculating an imaging operable perioduntil the time difference exceeds a predetermined threshold (an upperlimit of the time difference for emitting the radiation in theaccumulating period).

Further, the imaging controller 31 has a function of calculating thenumber of images that can be further taken from the calculated imagingoperable period and the frame rate.

With this configuration, it is possible to continue the imaging processuntil the number of images taken reaches the calculated number evenafter the communication between the clock information source apparatus2, 4 and the imaging apparatus 3 is lost.

Example 5-2

As described in Example 5-1, there is a problem that an imaging processhas to be canceled when the communication is lost. To cope with theproblem, in Example 5-1, the number of images that can be further takenis calculated, and the imaging process is continued until the number ofimages taken reaches the calculated number. Instead, a determination maybe made as to whether to continue the imaging process based on therequired number of images (the number of images that has not be takenyet) and the accuracy of the oscillators of the irradiating apparatus 1and the imaging apparatus 3.

Specifically, the same parameter as in Example 5-1 is stored in thestorage 35 beforehand.

The imaging controller 31 of Example 5-1 (which has the function ofcalculating the number of images that can be further taken) further hasa function of comparing the calculated number of images that can befurther taken with the number of images that have not been taken yet.

The imaging controller 31 further has the following function. When thenumber of images that can be further taken is equal to or greater thanthe number of images that have not been taken yet, the imagingcontroller 31 continues the imaging process. When the number of imagesthat can be further taken is less than the number of images that havenot been taken yet, the imaging controller 31 performs an output such asgiving a notification that the imaging process cannot be continued tothe last, giving a notification that imaging is disabled, or cancellingthe imaging process.

In this configuration, the imaging process can be continued when thecommunication between the clock information source apparatus 2, 4 andthe imaging apparatus 3 is lost but the imaging process can be continueduntil the preset number of images are taken.

When the imaging process is continued, a notification may be given tothe user that the connection is lost but the imaging process can andwill be continued to the last.

When the imaging process is continued after loss of the communication,the image data of images that are taken while the communication is lostmay be associated with specific information (flag or the like).

Example 5-3

In Example 5-1, temperature may be further used to calculate the numberof images that can be further taken. That is, temperature may be used asone of the factors that affect the accuracy of the oscillation cycle ofthe oscillators.

Specifically, the relationship between the temperature and theoscillation cycle of the oscillators of the irradiating apparatus 1 andthe imaging apparatus 3 is stored in the storage 35 beforehand asillustrated in FIG. 45A. In the figure, the solid line represents atheoretical value, and the upper and lower dashed lines representrespectively the upper and lower limits based on the accuracy.

The imaging controller 31 has a function of predicting the change of thetime difference (time lag) between the first clock information of theclock information source apparatus 2, 4 and the second clock informationof the imager clock 37 from the time difference immediately after lossof the connection, the clock rate of the clock information sourceapparatus 2, 4 and the imager clock 37 and the relationship between thefactors and the accuracy stored in the storage 35.

The imaging controller 31 also has the same functions as in Example 5-1.

Since the temperature of the oscillators largely affects the accuracy ofthe oscillation cycle of the oscillators compared to the other factors,this configuration allows predicting the change of the time differencewith higher accuracy as illustrated in FIG. 45B. As a result, the numberof images that can be further taken can be calculated with higheraccuracy.

As with Example 5-2, a determination as to whether the imaging processcan be continued to the last may be made. If so, the imaging process maybe continued. If not, the imaging process may be cancelled.

Example 6-1

In the above-described embodiments, once the synchronization isperformed, further synchronization may not be performed any more.

Specifically, the imaging controller 31 has a function of performing thetime synchronization when the first clock information is sent for thefirst time after the user presses down the exposure switch.

Further, the imaging controller 31 has a function of not updating theclock information of the imager clock 37 while the exposure switch ispressed down after the synchronization is checked.

This prevents the operation timing of the imaging apparatus 3 from beingchanged during the imaging period. Therefore, the imaging process can bestably performed.

The imaging controller 31 may measure the difference between the firstclock information and the second clock information when the first clockinformation is sent for the first time after the time synchronization,so as to check whether the time synchronization has been successfullyperformed or whether the time difference after the time synchronizationis equal to or less than a predetermined value.

This can prevent an image from being taken when the apparatuses areactually not synchronized with each other. The subject S can thus beprevented from being exposed to unnecessary radiation.

Example 6-2

Another problem in the above-described embodiments is that when thesynchronization is performed irregularly, the change of the operationtiming of the irradiating apparatus 1 or the imaging apparatus 3 affectsthe output images, which may lead to a misdiagnosis.

To cope with the problem, in the above-described embodiments, thesynchronization may be performed at the timing of the imaging cycle(i.e. every time a frame is taken) during the imaging period asillustrated in FIG. 46 .

In this configuration, the synchronization is performed at the timing oftaking each frame image. This can prevent only a certain frame imagefrom being affected by the synchronization of the operation timing.

This influence of the change of the operation timing on the image tendsto become noticeable when the difference of a feature value betweenadjacent frame images is used for an analysis. However, theabove-described configuration can also eliminate such influence on ananalysis that uses the difference of a feature value.

The cycle of sending the first clock information from the clockinformation source apparatus 2, 4 may be equal to the imaging cycle or avalue obtained by dividing the imaging cycle by an integer.

In this case, the timing of the synchronization may be shifted by apredetermined phase with respect to the timing of sending the firstclock information.

Example 6-3

As described in Example 5-1, there is a problem that irregularsynchronization may affects output images. To cope with the problem, inExample 5-1, the synchronization is performed every time a frame imageis taken. Instead, the synchronization may be performed every time tensof frame images are taken, for example, as illustrated in FIG. 47 .

This can reduce the influence on frame images even in a lengthy serialimaging process.

In this configuration, it is preferred that the synchronization isperformed at a time point in the imaging period at which thesynchronization is less likely to affect the images.

For example, when serial images of a lung field are taken, thesynchronization is performed not in the course of taking a breath in orout (when the movement of the lung is significant), which is importantfor making a diagnosis, but at the completion of taking a breath in orout (when the movement of the lung is small) or the like.

This can prevent an image taken at the timing important for a diagnosisfrom being affected by the change of the operation timing.

Example 6-4

As described in Example 5-1, there is a problem that irregularsynchronization may affect output images. To cope with the problem, inExample 5-1, the synchronization is performed every time a frame imageis taken. Instead, the synchronization may be performed every timeseveral frame images are taken, for example, as illustrated in FIG. 48 .

When the synchronization is performed in every frame as described inExample 6-1, the lengthy processing of the synchronization cannotsometimes be completed within the time of taking a frame image. This mayaffect the next frame image. On the other hand, when the synchronizationis performed in every tens of frames as described in Example 6-2, thetime lag of the operation timing may sometimes become too large. Incontrast, in this configuration, the synchronization is performed atsuitable intervals. This can eliminate the influence of thesynchronization processing on the next frame as well as reduce theamount of change of the operation timing by the synchronization.Therefore, the influence of the synchronization on output images can bereduced.

After the clock information of the clocks is changed in a certain frame,relevant processing may be performed in the next or later frame.

This can spread the update of the clock information and the otherprocessing to two or more frames. Even when the other processing is aconsiderable burden, the clock information can be certainly updated atpredetermined timing.

Example 6-5

As described in Example 5-1, there is a problem that irregularsynchronization may affects output images. To cope with the problem, inExample 5-1, the synchronization is performed every time a frame imageis taken. Instead, the synchronization may be performed at intervalsthat are shorter than the imaging cycle (i.e. the synchronization may beperformed twice or more while one frame image is taken) as illustratedin FIG. 49 .

This can reduce the amount of change of the operation timing by thesynchronization and thus reduce the influence on output images.

Although not shown in the figure, the synchronization may be suspendedduring a specific step in the process of taking each frame image.

For example, the specific step may be accumulation of charges, readingand transfer of image data, initialization or the like that is performedby the imaging apparatus 3.

Since the synchronization during such specific steps is more likely toaffect output images, this configuration can reduce the influence onoutput images. Specifically, suspension of the synchronization duringaccumulation can reduce the influence on the image contrast of eachframe image. Further, suspension of the synchronization during readingand transfer can reduce the influence of the noise.

Example 6-6

In the above-described embodiments, the synchronization may affectoutput images. To avoid this, it is sometimes desired not to perform thesynchronization depending on an imaging technique or an analyzing methodused as long as the time lag of the operation is within a predeterminedrange.

To address the need, in the above-described embodiments, the timedifference (time lag) between the first clock information of the clockinformation source apparatus 2, 4 and the second clock information ofthe imager clock 37 may be periodically measured, and thesynchronization may be performed only when the time difference exceeds athreshold as illustrated in FIG. 50 .

This can reduce the synchronization processing as few as possible andthereby reduce the risk of the influences on output images.

The synchronization may be suspended during a specific step even whenthe time difference exceeds the threshold. In this case, thesynchronization may be performed after the specific step is completed.

For example, the specific step may be accumulation of charges, readingand transfer of image data, initialization or the like that is performedby the imaging apparatus 3.

Since the synchronization during such specific steps may affect images,this can reduce the influence on output images as little as possible.

When frame images are stored, a frame image that is taken at the timingof the synchronization may be associated with information indicating thesynchronization is performed.

This allows later specifying the frame image that was taken when thesynchronization was performed. When the images are affected by thesynchronization, specifying the frame image enables making adetermination as to whether the influence shown in the images is due tothe synchronization or the subject to be diagnosed.

Example 7-1

Another problem in the above-described embodiments is that when a timelag occurs between the operation of the irradiating apparatus 1 and theoperation of the imaging apparatus 3, whether the image quality isaffected depends on which apparatus is selected as the base of thesynchronization.

To cope with the problem, in the above-described embodiments, theoperation of the irradiating apparatus 1 may be aligned with theoperation of the imaging apparatus 3 when a time lag of the operation isdetected.

Specifically, as illustrated in FIG. 51 , the timing of irradiation isdelayed when it is too early, or the timing of irradiation is put aheadwhen it is too late.

While correction of the operation of the imaging apparatus 3 is likelyto cause variation of contrast between frame images, this configurationcan prevent such variation of contrast.

As in Example 6-6, when frame images are stored, a frame image that istaken at the timing of the synchronization may be associated withinformation indicating the synchronization is performed.

This allows later specifying the frame image that was taken when thesynchronization was performed. When the images are affected by thesynchronization, specifying the frame image enables making adetermination as to whether the influence shown in the images is due tothe synchronization or the subject to be diagnosed.

Example 7-2

As described in Example 7-1, there is a problem that whether the imagequality is affected depends on which apparatus is selected as thereference of the synchronization. To cope with the problem, in Example7-1, the operation of the irradiating apparatus 1 is corrected based onthe operation of the imaging apparatus 3. Instead, the operation of theimaging apparatus 3 may be aligned with the operation of the irradiatingapparatus 1 when a time lag of the operation is detected.

Specifically, as illustrated in FIG. 52 , initialization is shortened toput ahead the timing of accumulation when it is too late, orinitialization is extended to delay the timing of accumulation when itis too early.

The synchronization may be suspended during a specific step even when itbecomes necessary to perform the synchronization. In this case, thesynchronization may be performed after the specific step is completed.

For example, the specific step may be accumulation of charges, readingand transfer of image data, initialization or the like that is performedby the imaging apparatus 3.

Since the synchronization during such specific steps may affect images,this can reduce the influence on output images as little as possible.

As in Example 7-1, when frame images are stored, a frame image that istaken at the timing of the synchronization may be associated withinformation indicating the synchronization is performed.

This allows later specifying the frame image that was taken when thesynchronization was performed. When the images are affected by thesynchronization, specifying the frame image enables making adetermination as to whether the influence shown in the images is due tothe synchronization or the subject to be diagnosed.

Example 7-3

As described in Example 7-1, there is a problem that whether the imagequality is affected depends on which apparatus is selected as thereference of the synchronization. To cope with the problem, in Example7-1, the operation of the irradiating apparatus 1 is corrected based onthe operation of the imaging apparatus 3. Instead, the operation of boththe irradiating apparatus 1 and the imaging apparatus 3 may be correctedas illustrated in FIG. 53 .

Correction of the operation of the irradiating apparatus 1 andcorrection of the operation of the imaging apparatus 3 may haverespectively different influences on images. In such cases, it isdifficult to eliminate the influences when only one of them iscorrected. However, in this configuration, the operation of theirradiating apparatus and the operation of the imaging apparatus areboth slightly corrected. This can reduce the influences on images.

The first clock information of the clock information source apparatus 2,4 may be used as a reference to correct the operation of both theirradiating apparatus 1 and the radiation detector.

Since both the irradiating apparatus 1 and the imaging apparatus 3 areconnected to the clock information source apparatus 2, 4 as thereference, the synchronization can be performed stably.

The clock information source apparatus 2, 4 can communicate with anexternal network according to a communication standard such as IEEE 1588to perform the time synchronization in cooperation with another externalclock. Therefore, more accurate clock information can be used as thereference.

The irradiating apparatus 1 and the imaging apparatus 3 generate heatduring operation, which may sometimes affect the reference oscillatorsof the internal clocks. However, the clock information source apparatus2, 4 can be disposed away from the irradiating apparatus 1 and theimaging apparatus 3 and is less likely to be affected by the heat.Therefore, the clock information source apparatus 2, 4 can output theclock information more stably.

The system may be configured to be able to select an apparatus to becorrected from among the irradiating apparatus 1, the imaging apparatus3 and both of them according to the contents of an image to be taken andthe imaging technique used. Since the synchronization method is selectedaccording to the imaging method and the imaging technique, theinfluences on images can be kept within the allowable range that variesdepending on the imaging method and the imaging technique.

When the operation of both apparatuses is corrected, the proportion ofthe correction may be changeable. For example, in an analysis ofbloodstream, it is important to reduce the variation of contrast betweenadjacent frame images. In order to reduce the contrast variation, forexample, the proportion of the correction may be selected so that theamount of correction of the irradiating apparatus 1 is greater than theamount of correction of the imaging apparatus 3.

Example 7-4

As described in Example 7-1, there is a problem that whether the imagequality is affected depends on which apparatus is selected as thereference of the synchronization. To cope with the problem, in Example7-1 to Example 7-3, the operation of at least one of the irradiatingapparatus 1 and the imaging apparatus 3 is corrected. However, even inthese configurations, images may sometimes be still affected when thesynchronization is performed during a specific step.

To cope with the problem, in the above-described embodiments, thesynchronization may be suspended during a specific step in the processof taking each frame image.

For example, the specific step may be accumulation of charges, readingand transfer of image data, initialization or the like that is performedby the imaging apparatus 3.

Since the synchronization during such specific steps is more likely toaffect images, this can reduce the influence on output images.

Example 8-1

In the above-described embodiments, the imaging apparatus 3C maygenerate the reading start times from the imaging sequence start timeand the frame rate by itself while the controlling apparatus 12similarly generate the exposure start times by itself. In this case,when the frame rate is changed at different timing between the imagingapparatus 3C and the controlling apparatus 12, the imaging fails. Forexample, when frame rate information is sent from the controllingapparatus 12 to the imaging apparatus 3C, the timing of changing theframe rate at the imaging apparatus 3C may sometimes be delayed due tocommunication delay such as packet loss.

To cope with the problem, in the above-described embodiments, thecontrolling apparatus 12 and the imaging apparatus 3C may count commonframe numbers. When the controlling apparatus 12 (or the imagingapparatus 3C) receives an instruction to change the frame rate, it maysend a rate-changing frame number and the frame rate to the imagingapparatus 3C.

To avoid the influence of communication delay, the rate-changing framenumber may be calculated as the sum of the current frame number and acertain number that is greater than “expected communication delay/framecycle+1”.

When the number of counts reaches the rate-changing frame number, thecontrolling apparatus 12A and the imaging apparatus 3C changes the framerate.

In this configuration, the timing of changing the frame rate is lesslikely to be delayed.

Instead of the rate-changing frame number, a rate-changing time may benotified. When the rate-changing time is close to a frame transitiontime, the timing of changing the frame rate may not be synchronizeddepending on the synchronization accuracy of the clocks. To avoid this,the rate-changing time is selected so that it is not within the rangesof frame transition times ±α. The value α is greater than the expectedsynchronization accuracy in an imaging process.

Example 8-2

As described in Example 8-1, there is a problem that when the imagingapparatus 3C generates the reading start times by itself while thecontrolling apparatus 12 generates the exposure start times, the timingof changing the frame rate at the imaging apparatus 3C is sometimesdelayed due to communication delay. To cope with the problem, Example8-1 has the following configuration. That is, the controlling apparatus12 and the imaging apparatus 3C count the common frame numbers. When thecontrolling apparatus 12 receives an instruction to change the framerate, it sends the rate-changing frame number and the frame rate to theimaging apparatus 3C. Instead, the imaging apparatus 3C may read animage at the maximum frame rate while the controlling apparatus 12performs an exposure once every predetermined reading operations of theimaging apparatus 3C so that images are taken at a desired frame rate.

For example, assuming that images are taken at 7.5 fps with the systemhaving the maximum frame rate of 15 fps. In this case, the imagingapparatus 3C reads an image at 15 fps while the controlling apparatus 12performs a single exposure every time the imaging apparatus 3C reads twoframes.

In this configuration, the imaging apparatus can generate the readingstart times by itself while the radiation controlling apparatus cangenerate the exposure start times by itself. Accordingly, the imagingsequence start time and the frame rate are the only information that hasto be shared between the imaging apparatus 3C and the controllingapparatus 12A. This can reduce the risk of an imaging failure caused bycommunication delay or packet loss between the imaging apparatus 3C andthe controlling apparatus 12C or the like. Such an imaging failureoccurs when a reading start time is received after the time pointspecified by the reading start time, or when an exposure start time isreceived after the time point specified by the exposure start time.

In this configuration, unlike Example 8-1, it is not essential toexchange frame rate changing information between the controllingapparatus 12A and the imaging apparatus 3C when the frame rate ischanged. Accordingly, the frame rate can be changed in a moment. Thisallows the user to select a desired frame rate at desired timing.Therefore, the usability of the system is improved.

Example 8-3

In Example 8-2, the imaging apparatus 3C reads several frames at themaximum frame rate while an exposure is performed. Therefore, some ofthe frame images generated by the imaging apparatus 3C are unexposedimages (hereinafter referred to as white images). A problem with this isthat such white images degrade the visibility of a dynamic image.

To cope with the problem, white images may be removed in Example 8-2.

Specifically, the average or maximum value of the signal values of thepixels in a predetermined area (including the whole area) is comparedwith a predetermined threshold with respect to each frame. When theaverage or maximum value is equal to or less than the threshold, theimage is determined as a white image. Images determined as white imagesmay be deleted or associated with white image attribute information sothat the frame images associated with the attribute information are notdisplayed.

The above-described processing may be performed by either the imagingapparatus 3C or the console 14. When the above-described processing isperformed by the imaging apparatus 3C, it is possible to reduce theamount of data sent from the imaging apparatus 3C to the console 14.This can reduce the occurrence of delay between taking frame images anddisplaying them on the console 14.

Example 8-4

As described in Example 8-3, there is a problem in Example 8-2 that someof frame images to be generated are white images. To cope with theproblem, in Example 8-3, a frame image is removed when it is determinedas a white image based on the signal values of pixels of the frameimage. Instead, the determination may be made based on the frame numberof each frame image, and a frame image that is determined as a whiteimage is removed.

Specifically, according to a rule that is common between the controllingapparatus 12 and the imaging apparatus 3C, unique frame numbers (e.g.sequential numbers) are given to all frames that are taken in a serialimaging process.

Further, the controlling apparatus 12 has a function of associatinginformation representing whether the image is exposed with each framenumber, storing it as exposed frame information and sending the exposedframe information to the imaging apparatus 3C or the console 14.

The imaging apparatus 3C or the console 14 has a function of storing aclock time (e.g. the exposure start time, the exposure end time, acertain time in a frame, or the like) of each frame and referencing thereceived exposure frame numbers to delete unexposed frame images or toprohibit unexposed frame images from being displayed.

Alternatively, the controlling apparatus 12 may have a function ofstoring clock times of exposed frames and unexposed frames asinformation indicating whether each frame image is exposed and sendingthe information to the imaging apparatus 3 or the console 14. Theimaging apparatus 3C or the console 14 has a function of storing theclock times of the frames and comparing them with the receivedinformation so as to delete the unexposed frame images or prohibit theunexposed frame images from being displayed.

This configuration eliminates the necessity of making a determination asto whether each image is a white image. This can reduce the load on theimaging apparatus or the console and thereby reduce the delay betweentaking frame images and displaying them on the console.

Example 8-5

Regarding the above-described embodiments, there is a need for a systemthat can perform an exposure and the subsequent reading step at suitabletiming after the user presses down the exposure switch to start animaging process.

For example, when the tube 13 is rotated during an imaging period, thesuitable timing may be the timing when the tube 12 at a predeterminedposition (or any one of predetermined positions). When the subject S isasked to breath according to an announcement, the suitable timing may bethe timing(s) when a predetermined message is announced. When images aretaken while the subject S is changing his/her position, the suitabletiming may be the timing when the subject S is in a predeterminedposition.

To address the need, in the above-described embodiments, the controllingapparatus 12 may determine an exposure start time and a reading starttime when it reaches the suitable timing, and the reading start time issent from the radiation controlling apparatus 12A to the imagingapparatus 3C. Then, the controlling apparatus 12 starts an exposure whenthe clock information of its own clock reaches the exposure start timewhile the imaging apparatus starts a reading operation when the clockinformation of its own clock reaches the reading start time.

The exposure start time and the reading start time are determined basedon the expected latency of the wireless communication.

The reading start time is calculated as the sum of the synchronizedclock information at the suitable timing and the longer period of timebetween “the period of time from the current time until the imagingapparatus receives the reading start time and gets ready for the readingoperation (which is determined also based on the expected latency of thewireless communication)” and “a period of time required for thecontrolling apparatus 12 to get ready for exposure+an exposure time of asingle frame”.

Further, the exposure start time is at least “the exposure time of asingle frame” earlier than the reading start time.

This can prevent an imaging failure that occurs when the imagingapparatus 3C receives a reading start time after the time pointspecified by the reading start time.

Instead of the controlling apparatus 12A, the imaging apparatus 3C maydetermine the exposure start time and the reading start time.

Example 8-6

As described in Example 8-5, there is a need for a system that canperform an exposure and the subsequent reading step at suitable timingafter the user presses down the exposure switch to start an imagingprocess. To address the need, in Example 8-5, the controlling apparatus12 determines an exposure start time and a reading start time when itreaches the suitable timing. Instead, the imaging apparatus 3C maygenerate a reading start time from the imaging sequence start time andthe frame rate by itself while the controlling apparatus 12 generatesthe exposure start times by itself, so that the imaging apparatus 3C andthe controlling apparatus 12 can always take images at the maximum framerate. The imaging apparatus constantly performs the reading operationsat the maximum frame rate while the controlling apparatus 12 controlsthe tube 13 to start exposure at the first exposure timing after thesuitable timing.

In example 1-5, when the expected latency of the wireless communicationis large, it takes a long time from the desired timing to the start ofexposure. As a result, the exposure cannot sometimes be performed at thespecified timing, which results in an imaging failure.

However, in this configuration, the maximum delay of the start ofexposure from the desired timing can be reduced to one cycle at themaximum frame rate (e.g. approximately 66.6 ms when the frame rate is 15fps). Therefore, an imaging failure due to the delay can be prevented.

In this configuration, white images are generated. However, problemswith white images can be solved by applying the configuration of Example8-3 or the like.

Example 9-1

In the above-described embodiments, the clock information of thesynchronized clocks is used to control exposure and reading. When thesynchronization accuracy of the clocks is decreased during a series ofexposures for taking two or more serial frame images, thesynchronization between exposure and reading may sometimes be lost.

To cope with the problem, in the above-described embodiments, the clockinformation may be used to perform the synchronization only at the startof an imaging sequence.

Specifically, the radiation controller 121 has a function of startingthe operation to emit radiation at predetermined timing when the clockinformation of the second irradiator clock 126 reaches an imaging starttrigger time.

Further, the imaging controller 31 has a function of starting theoperation to read charges at predetermined timing when the clockinformation of the second imager clock 39C reaches an imaging starttime.

The timing of the reading sequence performed by the imaging apparatus 3Cis preset so as to be later than the timing of the reading sequenceperformed by the controlling apparatus 12A.

In this configuration, once the imaging apparatus 3C starts controllingthe reading sequence based on the clock information and the controllingapparatus 12A starts controlling the exposure sequence based on theclock information, the clock information is not used for performing theexposure and the reading as illustrated in FIG. 54 . As illustrated inFIG. 55 , even when an abnormality occurs in the clock informationsource apparatus 2, 4 during an imaging period so that the clockinformation of the second clocks 39C, 126 are changed, the controllingapparatus 12A and the imaging apparatus 3C can continue their operationswithout being affected by the abnormality.

Example 9-2

In the above-described embodiments, the imaging apparatus 3C includesthe imager clock 37 and the second imager clock 39, and the imager clock37 is synchronized with the clock information source apparatus 2, 4regardless of the operation mode of the second imager clock 39. Thisconfiguration is designed to use a typical WLAN module.

Instead, a customized WLAN module may be used to omit the imager clock37. When the second imager clock 39 is in the synchronization mode, thesecond imager clock 39C is synchronized with the clock informationsource apparatus 2, 4.

The omission of the imager clock 37 reduces the number of clocks used inthe system. This can reduce the size of the circuit and software orsimplify them.

In this example, the imager clock 37 of the imaging apparatus 3C isomitted. Instead, the irradiator clock 125 of the controlling apparatus12 may be omitted, and the second irradiator clock 126 may besynchronized with the clock information source apparatus 2, 4.

Example 9-3

In the above-described embodiments, the imaging sequence start time isdetermined when the irradiation-ready signal is received from the highvoltage generator 122. However, the wiring and the apparatuses have tobe often modified to send the irradiation-ready signal depending on thecharacteristics and the system configuration of the high voltagegenerator 122, which results in the higher development cost.

To cope with the problem, in the above described embodiments, analternative trigger that is different from the irradiation-ready signalmay be used to determine the imaging sequence start time.

Examples of alternative triggers includes the following (1) to (3).

(1) The first button of the exposure switch is pressed down.

(2) The second button of the exposure switch is pressed down.

(3) A user instruction is received on a UI such as the console 14, theimaging apparatus 3, the controlling apparatus 12 or the exposure switch15 a.

The period of time after the first button of the exposure switch ispressed down until the second button is pressed down varies depending onthe user operation. Further, after the first button of the exposureswitch is pressed down, the high voltage generator 122 has to finish arotor-up operation of the rotating anode of the tube 13 to get ready forirradiation. However, the rotor-up time also varies depending on theconditions. When the above-described trigger (1) is used as thealternative trigger, such variations makes it impossible to predict thelength of time after the first button of the exposure switch is presseddown until the system gets ready for irradiation. Tat is, a problem inthis configuration is that the exposure start times and the readingstart times cannot be determined.

To cope with the problem, it is effective to modify Step 6 to Step 11 ofthe above-described flow of a serial imaging process as follows. Step 1to Step 5 and Step 12 and later are the same as those of theabove-described flow. Further, the other supplementary explanations andthe like in the above description are omitted.

Step 6

When the controlling apparatus 12 detects a user operation of pressingdown the first button of the exposure switch (the controlling apparatus12 receives an imaging start signal), it sends a corresponding commandto the imaging apparatus 3 to notify the detection.

Step 7

When the imaging apparatus 3 receives the command, it shifts into theimaging-ready state.

Then, the imaging apparatus 3 and the controlling apparatus 12 wait forthe second clocks 39, 126 to update their own second clock informationto the first clock information of the clock information source apparatus2, 4.

When the update of the clock information of the second clocks 39, 126 iscompleted, the imaging apparatus 3 calculates the imaging sequence starttime by adding the clock information of the second clock 39 at the timeof the completion to the imaging sequence waiting time stored in thestorage 35. The imaging apparatus 3 stores the calculated imagingsequence start time in the storage 35 and sends it to the controllingapparatus 12.

In this example, the imaging apparatus 3 sends the imaging sequencestart time to the controlling apparatus 12. Instead, the controllingapparatus 12 may calculate the imaging sequence start time by adding theclock information of the second clock 126 at the time of the completionto the imaging sequence waiting time stored in the storage 123. Thecontrolling apparatus 12 may then store the calculated imaging sequencestart time in the storage 126 and send it to the imaging apparatus 3.

Step 8

Even after the synchronization with each other is completed, the imagingapparatus 3 and the controlling apparatus 12 continue to make adetermination as to whether they are in synchronization with each other.

After the irradiation-ready signal is sent from the high voltagegenerator 122 to the controller 121, the imaging apparatus 3 and thecontrolling apparatus 12 may sometimes detect failure of thesynchronization in the period of time after the completion of thesynchronization between the imaging apparatus 3 and the controllingapparatus 12 until the start of reading the last frame image of theserial imaging process. In this case, the imaging apparatus 3 and thecontrolling apparatus 12 operate the second clocks 39, 126 in thefree-running mode in the period of time after the detection until thestart of reading the last frame image of the serial imaging process, andthen return the operation mode to the synchronization mode. When theimaging apparatus 3 and the controlling apparatus 12 detect failure ofthe synchronization, they switch the operation mode to the free-runningmode before updating the clock information of the second clocks 39, 126to the clock information of the clocks 37, 125. This can prevent theclock information of the second clocks 39, 126 from being set to anabnormal value.

Step 9

When the controlling apparatus 12 receives the imaging sequence starttime from the imaging apparatus 3, it stores the received imagingsequence start time in the storage 123.

Then, the controlling apparatus 12 generates exposure start times of therespective frame images from the stored imaging sequence start time andthe frame rate (e.g. 15 fps).

For example, the exposure start times are generated as follows.Specifically, the exposure start time of the first frame image is set tothe same time as the imaging sequence start time, and the imaging cycletime (=1/frame rate) is cumulatively added thereto to obtain theexposure start times of the second and later frame images. That is, theexposure start time of the N-th frame image=the imaging sequence starttime+(frame number N−1)×the imaging cycle time.

Step 10

The controller 121 sends to the high voltage generator 122 a signalrepresenting an instruction to start exposure of a frame every time theclock information of the second irradiator clock 126 reaches any one ofthe exposure start times of the respective frames.

As long as the high voltage generator 122 is ready for irradiation, itcontrols the tube 13 to emit the radiation R for a preset irradiationtime every time it receives the signal representing the instruction tostart exposure. That is, the controlling apparatus 12 controls the tube13 to emit the radiation R when the clock information of the secondirradiator clock 126 reaches a first predetermined value.

Step 11

When the controller 121 detects the occurrence of an event indicatingthe end of the imaging process, e.g. the first button of the exposureswitch 15 a is released, the number of frame images taken reaches themaximum number of frames stored in the storage 123, or when thecontroller 121 receives a shut-down notification from the high voltagegenerator 122 or the imaging apparatus 3, it sends a command to notifythe end of the imaging process to the imaging apparatus 3 via thecommunicator 124 and does not send any further instruction to startexposure to the high voltage generator 122 during the current imagingprocess. That is, the imaging process ends.

Further, after the second button of the exposure switch is pressed down,the high voltage generator 122 has to finish a rotor-up operation of therotating anode of the tube 13 to get ready for irradiation. However, therotor-up time also varies depending on the conditions. When theabove-described trigger (2) is used as the alternative trigger, thelongest expected rotor-up time has to be set as the period of time afterthe second button of the exposure switch is pressed down until thesystem gets ready for irradiation. That is, the user has to wait for arelatively longtime after the second button of the exposure switch ispressed down until the system starts taking images. This causes aproblem that the system cannot start taking images at intended timing(e.g. at the maximum inspiratory level).

To cope with the problem, the flow of the serial imaging process thatuses the above-described trigger (1) as the alternative trigger may bemodified such that “the first button of the exposure switch” is changedto “the second button of the exposure switch”.

The above-described trigger (3) may be used as the alternative trigger.In this case, when neither the first button nor the second button of theexposure switch is connected via the controlling apparatus 12 (i.e. theexposure switch is directly connected to the tube 13), a userinstruction to start an imaging process is input on a UI such as theconsole 14, the imaging apparatus 3, the controlling apparatus 12 or theexposure switch. As in the case in which the above-described trigger (1)is used as the alternative trigger, it is impossible to predict thelength of time after the user instruction until the system gets readyfor irradiation. That is, a problem in this configuration is that theexposure start times and the reading start times cannot be determined.

To cope with the problem, the flow of the serial imaging process thatuses the above-described trigger (1) as the alternative trigger may bemodified such that “the first button of the exposure switch beingpressed down” is changed to “a user instruction on a UI such as theconsole 14 the imaging apparatus 3, the controlling apparatus 12 or theexposure switch 15 a”.

Example 9-4

A problem in Example 9-3 is that white images are generated until thehigh voltage generator 122 and the tube 13 gets ready for irradiation.This problem can be solved by applying the configuration of Example 8-3or the like.

Example 9-5

As described in Example 9-3, there is a problem that white images aregenerated until the high voltage generator 122 and the tube 13 get readyfor irradiation. To cope with the problem, in Example 9-3, thedetermination as to whether a frame image is a white image is made basedon pixels of the frame image. Instead, when the controller 121 canobtain from the high voltage generator 122 information indicatingradiation is being emitted, the determination may be made based on theinformation.

Specifically, the radiation controller 121 has a function of obtainingthe clock information of the second clock 126 at the time when theradiation controller 121 obtains the information indicating emission ofradiation for the first time after the imaging sequence start time. Theradiation controller 121 stores the obtained clock information in thestorage 123 and sends it to the console 14 or the imaging apparatus 3.

Further, the imaging controller 31 has a function of comparing thereading start times of the frames stored in the storage 35 with thereceived clock information at the time of the first irradiation anddeleting an unexposed frame image or prohibiting the console or the likefrom displaying an unexposed frame image.

This configuration eliminates the necessity of making the determinationas to whether each image is a white image based on pixels of the image.This can reduce the load on the imaging apparatus 3 or the console 14and thereby reduce the delay between taking frame images and displayingthem on the console 14.

Example 9-6

As described in Example 9-3, there is a problem that white images aregenerated until the high voltage generator 122 and the tube 13 get readyfor irradiation. To cope with the problem, in Example 9-3, thedetermination of whether a frame image is a white image is made based onpixels of the frame image. Instead, the imaging apparatus 3 may includea radiation sensor that can measure the dose of radiation. When themeasurement value of the radiation sensor exceeds a predeterminedthreshold after the imaging sequence start time, the imaging apparatus 3determines that the process of taking the first frame image is started.Then, the imaging apparatus 3 deletes the previous frame images orprohibits the previous images from being displayed.

This configuration eliminates the necessity of making the determinationas to whether each image is a white image based on pixels of the image.This can reduce the load on the imaging apparatus 3 or the console 14and thereby reduce the delay between taking frame images and displayingthem on the console 14.

Example 9-7

In Example 9-6, when the radiation detection accuracy of the radiationsensor is high enough to detect the minimum accumulated dose of eachframe, the measurement value of the radiation sensor can be read andcompared with a threshold with respect to each frame. The sensor isreset with respect to each frame to prepare for the next frame.

However, when the radiation detection accuracy of the radiation sensoris less than the minimum accumulated dose of each frame, the sensor isnot be reset with respect to each frame, but the measurement value ofthe accumulated dose of two or more frames is compared with a threshold.When the measurement value exceeds the threshold, it is determined thatan exposure is started. In this configuration, an inexpensive radiationsensor with low detection performance can be used.

Example 9-8

It may sometimes take a long time after the first button of the exposureswitch is pressed down until the second button is pressed down. In thiscase, when the system of Example 9-7 is configured to compare theaccumulated dose of two or more frames a threshold, the radiation sensoraccumulates noise since it is not reset for a long time. As a result, itmay sometimes be erroneously determined that the dose exceeds thethreshold.

To cope with the problem, the radiation sensor may be reset every time apredetermined time or a predetermined number of frames have elapsed.

Example 9-9

In the serial imaging process of the above-described embodiments, thenumber of frames exposed is equal to the number of frames read. However,some imaging systems require an unexposed frame (a frame that is onlyread) before the first exposed frame. For example, in order to obtain anunexposed frame image for the purpose of stabilization of thetemperature in the imaging apparatus or image processing, apredetermined number (or more) of frames are not exposed but only read.Then, the subsequent frames are exposed and read.

When the configurations of the above-described embodiments are appliedto such imaging systems that require unexposed frames, the control hasto be suitably switched according to whether unexposed frames or exposedframes are taken. Otherwise, radiation may be erroneously emitted whileunexposed frame images are taken. As a result, desired images are notobtained, and the imaging fails.

To cope with the problem, it is effective to change Step 6 to Step 16 ofthe above-described flow of the serial imaging process to the followingStep 6 to Step 15. Step 1 to Step 5 are the same as those of theabove-described flow. Further, the other supplementary explanations andthe like in the above description are omitted.

Step 6

When the synchronization between the clock 37 and the clock informationsource apparatus 2, 4 is completed, the imaging apparatus 3 shifts intoan imaging-ready state.

Then, the imaging apparatus 3 and the controlling apparatus 12 wait forthe second clocks 39, 126 to update their own second clock informationto the first clock information of the clock information source apparatus2, 4.

If the update of the clock information is not completed within apredetermined time, the console 14 may be informed of failure of thesynchronization. The console 14 may then display a message or the likeon a display (not shown) to inform the failure of the synchronization,to prompt the user to perform troubleshooting such as restart of theclock information source apparatus 2, 4 and checking the networkconfiguration, or to recommend using a wired connection to take animage. This can speed up recovery from an abnormality.

When the update of both the clock information of the second clocks 39,126 is completed, the imaging apparatus 3 calculates an imaging sequencestart time by adding an imaging sequence waiting time stored in thestorage 35 to the clock information of the second clock 39 at the timeof the completion. The imaging apparatus 3 stores the calculated imagingsequence start time in the storage 35 and sends it to the controllingapparatus 12.

In this example, the imaging apparatus 3 sends the imaging sequencestart time to the controlling apparatus 12. Instead, the controllingapparatus 12 may calculate the imaging sequence start time by adding theclock information of the second clock 126 at the time of the completionto the imaging sequence waiting time stored in the storage 123. Thecontrolling apparatus 12 may store the calculated imaging sequence starttime in the storage 126 and sends it to the imaging apparatus 3.

Step 7

Even after the synchronization with each other is completed, the imagingapparatus 3 and the controlling apparatus 12 continue to make adetermination as to whether they are in synchronization with each other.

When the imaging apparatus 3 and the controlling apparatus 12 detectfailure of the synchronization in the period of time after thecompletion of the synchronization of both the imaging apparatus 3 andthe controlling apparatus 12 in the imaging-ready state until the startof reading the last frame of the serial imaging process, they operatethe second clocks 39, 126 in the free-running mode in the period of timeafter the detection until the start of reading the last frame of theserial imaging process. Then, they return the operation mode to thesynchronization mode.

Step 8

The imaging apparatus 3 generates reading start times of the respectiveframes based on the imaging sequence start time stored in the storage123, the frame rate and the accumulation time of each frame image.

In order to avoid emitting radiation in a reading operation, theaccumulation time is longer than the irradiation time of each frame.

Step 9

When the controlling apparatus 12 receives the imaging sequence starttime from the imaging apparatus 3, it stores the received imagingsequence start time in the storage 123. Then, the controlling apparatus12 generates exposure start times of the respective frames from thestored imaging sequence start time and the frame rate (e.g. 15 fps).

Step 10

The imaging apparatus 3 starts reading charges accumulated in theradiation detector 32 to generate image data of a frame image every timethe clock information of the second imager clock 39 reaches any one ofthe reading start times of the respective frames. When the imagingapparatus 3 has finished reading frames that are necessary for warmingup (or when the imaging apparatus 3 has finished obtaining unexposedframe images that are necessary for image processing), it gives to thecontrolling apparatus 12 a notification that imaging is allowed. Evenafter giving the notification of allowance of exposure, the imagingapparatus 3 starts reading charges accumulated in the radiation detector32 to generate image data of a frame image every time the clockinformation of the second imager clock 39 reaches any one of the readingstart times of the respective frames.

Step 11

When the controller 121 of the controlling apparatus 12 detects a useroperation of pressing down the second button of the exposure switch 15 a(the controller 121 receives the imaging start signal), it sends acorresponding signal to the high voltage generator 122 and shifts into astand-by state to wait for the ready signal from the high voltagegenerator 122. The ready signal represents that the high voltagegenerator 122 is ready for irradiation.

When the high voltage generator 122 receives the imaging start signal,it starts preparation for irradiation. Specifically, the high voltagegenerator 122 prepares a voltage and a current to be output to the tube13 and instructs the tube 13 to start rotation of a rotating anode.

Step 12

The controller 121 does not instruct the high voltage generator 122 tostart exposure until it receives both the irradiation-ready signal fromthe high voltage generator 122 and the notification of allowance ofexposure from the imaging apparatus. When the controller 121 receivesboth signals, it sends a communication command to the imaging apparatusso as to give an irradiation-ready notification. Thereafter, thecontroller 121 sends to the high voltage generator 122 a signalrepresenting an instruction to start exposure every time the clockinformation of the second irradiator clock 126 reaches any one of theexposure start times of the respective frames.

The high voltage generator 122 controls the tube 13 to emit theradiation R for a preset irradiation time every time it receives thesignal representing the instruction to start exposure. That is, thecontrolling apparatus 12 controls the tube 13 to emit the radiation Rwhen the clock information of the second irradiator clock 126 reaches afirst predetermined value.

Step 13

When the controller 121 detects the occurrence of an event indicatingthe end of the imaging process, e.g. the second button of the exposureswitch 15 a is released, the number of frame images taken reaches themaximum number of frames stored in the storage 123, or the controller121 receives a shut-down notification from the high voltage generator122 or the imaging apparatus 3, it sends a command to notify thecompletion of the imaging process to the imaging apparatus 3 via thecommunicator 124 and does not send any further instruction to startexposure to the high voltage generator 122 during the current imagingprocess. That is, the imaging process ends.

The maximum number of frames may be a fixed value stored in the storage123. Alternatively, the maximum number of frames may be a value that isinput on the console 14 by the user, which is sent to the controllingapparatus 12 and stored in the storage 123.

Step 14

After receiving the irradiation-ready signal from the controllingapparatus 12, the imaging apparatus 3 starts reading charges accumulatedin the radiation detector 32 to generate image data of a frame imageevery time the clock information of the second imager clock 39 reachesany one of the reading start times of the respective frames.

Step 15

Then, the imaging apparatus 3 terminates the imaging process when itdetects the occurrence of an event indicating the end of the imagingprocess, e.g. the imaging apparatus 3 receives from the controllingapparatus 12 a command that notifies the completion of the imagingprocess, or the number of frame images taken reaches the maximum numberof frames stored in the storage 35.

Example 10-1

In the above-described embodiments, the controlling apparatus 12A andthe imaging apparatus 3 are connected in a wireless manner to perform aserial imaging process. However, when the imaging apparatus 3 is alsoconnected in a wired manner, it is preferred to switch to a method thatis less likely to be affected by a decrease of the accuracy of thesecond imager clock 39 and the error of the frequency of the oscillatorsof the imaging apparatus 3 and the controlling apparatus 12.

Specifically, the irradiation controlling apparatus 12 generates theexposure start times and the reading start times. The controllingapparatus 12 sends the reading start times to the imaging apparatus 3though a dedicated line and instructs the tube 13 to emit a radiation atthe exposure start times of the respective frames.

Then the imaging apparatus 3 starts reading operations at the readingstart times of the respective frames.

The imaging apparatus 3 may have a function of detecting the connectionstatus. When the imaging apparatus 3 detects a wired connection througha cable, it may select the wired serial imaging method as descried inthis example. When the imaging apparatus 3 determines that there is nowired connection through a cable, it may select the previously-describedserial imaging method.

This can reduce user operations and thereby improve the usability.

EXAMPLE 10-2

The above-described embodiments are intended for wireless serialimaging. However, the number of frames may be set to one. That is, thesame control can also be used for wireless still imaging. By using thesame control, it is possible to reduce the development cost.

When a wireless still imaging process is performed, the imaging methodmay be switched to a method that is less likely to be affected by adecrease of the accuracy of the clocks and the frequency error of theoscillators of the imaging apparatus 3 and the controlling apparatus 12(e.g. SRM imaging by AERO-DR, AERO-SYNC imaging or the like) so that thewireless still imaging process can be performed stably.

Further, the console 14 may have a function of switching the imagingmethod of the imaging apparatus 3 and the controlling apparatus 12according to whether the user selects wireless still imaging or wirelessserial imaging. This can reduce user operations and thereby improve theusability.

Example 11-1

The dynamic change of a radiographic image may be displayed along withthe dynamic change of biological information, or the relationshipbetween them may be analyzed, so that the user can understand thecondition of the subject S in more detail.

For example, a dynamic image of the chest of the subject S may be takenwith a pulse oximeter attached on the subject S. Then, information suchas the arterial oxygen saturation (SpO2) and the pulse rate can beobtained from the pulse oximeter while information on the lungventilation function can be obtained from the dynamic image. Byintegrally analyzing the information, it is possible to estimate thetemporal change of the respiratory function.

However, devices for measuring biological information such as a pulseoximeter are normally independent from a radiographic system, and theiroperation is based on their individual oscillators. Accordingly, a timedifference of the clock information occurs. When each of a device and aradiographic system includes an oscillator with a frequency allowablevariation of ±100 ppm, the maximum difference that can occur in one houris 720 ms (60 sec×60 min×±0.01%=360 ms, when the error of one clock is+360 ms while the error of the other clock is −360 ms). In this case,when a dynamic image is taken at 30 fps one hour after the clockinformation of the clocks are correctly synchronized with each other,the time difference between the dynamic image and the biologicalinformation can be approximately 22 frames at the maximum. Such data isnot suitable for displaying or analyzing a biological function on aframe basis.

Nowadays a variety of devices have a wireless LAN communicationfunction. In the above-described embodiments, a bioinstrumentationdevice 6 may be connected to the clock information source apparatus 2, 4as illustrated in FIG. 56 , and the imaging system 100 and thebioinstrumentation device 6 may be synchronized with each other based onthe first clock information of the clock information source apparatus 2,4

Specifically, the imaging system 100 has a function of associatingcorresponding clock times with frame images when storing the frameimages. For example, each frame image is associated with the exposurestart time, the exposure end time or the reading start time (a timestamp) of the frame.

The bioinstrumentation device 6 has a function of associating the clockinformation at the time of sampling biological information with eachsampling value when storing the sampling value.

The image data of the radiographic image and the biological informationare sent to an apparatus that integrally analyze and display theradiographic image and the biological information, so that the frameimages and the sampling values are displayed in synchronization witheach other according to the associated clock information. That is, it ispossible to display the temporal change of both the frame image and thebiological information without any time difference between them.

Further, in addition to display them, it is also possible to use theclock information to understand what biological changes occurred at thesame time.

In addition to the clock information source apparatus 2, 4 and thebioinstrumentation device 6, a third device and more may be furtherconnected.

Instead of wireless LAN, the synchronization may be performed accordingto IEEE1588 or NTP or by using an atomic clock.

The frequency band of wireless LAN may be selectable. In thisconfiguration, for example, when the bioinstrumentation device 6 (pulseoximeter or the like) to be connected supports only 2.4 GHz WLAN, thefrequency band of the wireless LAN of the imaging system 100 can be setto 2.4 GHz.

A list of devices that are potentially connected to the imaging system10 may be prestored in the console 14 or the like along with theavailable frequency range thereof. When a device is connected to theconsole 14 via the clock information source apparatus 2, 4, the console14 references the stored list and changes the frequency range of theimaging apparatus 3 and the controlling apparatus 12. This can eliminatethe necessity of checking the frequency range or a user operation forswitching the frequency range and thereby improve the usability.

When the TSF is used, the synchronization can be performed to anaccuracy of tens to hundreds of microseconds. In this case, for example,when a dynamic image is taken at 30 fps, i.e. the imaging cycle is 33.3ms, the time difference can be reduced to less than a single frame.Accordingly, radiographic frame images can be associated with samplingvalues of biological information based on time with respect to eachframe. Therefore, the images and the sampling values can be displayedand analyzed with higher accuracy.

Example 11-2

As described in Example 11-1, there is a problem that a time differenceof the clock information occurs since the bioinstrumentation device andthe radiographic system are normally independent from each other and theoperation thereof is based on the individual oscillators. To cope withthe problem, in Example 11-1, the bioinstrumentation device is connectedto the clock information source apparatus 2, 4. Further, the TSF may beused to perform the synchronization. However, some wireless LAN modulescannot use the TSF to read clock information from an external device.

When the bioinstrumentation device uses such a wireless LAN module, itis required to modify or replace the wireless LAN module or to correctthe hardware. This requires long development time and high cost.

In such cases, it is possible to select a more common synchronizationmethod that can be implemented in a software, such as IEEE 1588 or NTP.However, when the NTP is used for controlling the timing of exposure andreading in a radiographic serial imaging process, the insufficient timeaccuracy sometimes causes an imaging failure.

When the system and the device use different synchronization methods,e.g. one uses the NTP while the other uses the TSF of WLAN, the imagecannot be displayed or analyzed in synchronization with the measurementresult due to the difference in definition of time stamp values.

To cope with the problem, in the above-described embodiments, twosynchronization methods may be used in parallel as illustrated in FIG.57 .

Specifically, the imaging system 100, which requires accurate timemanagement for the control, uses an accurate time synchronization method(the TSF of WLAN or the like) to perform the synchronization. However,the imaging system 100 uses a normal time synchronization method to adda time stamp to an output such as a frame image.

On the other hand, the bioinstrumentation device 6 (e.g. a pulseoximeter or the like), which does not require accurate time managementfor the control, uses the normal time synchronization method to add atime stamp to an output such as heart rate.

In this configuration, frame images taken by the imaging system 100 canbe associated with sampling values measured by an external device suchas the bioinstrumentation device 6 based on time without anymodification of the hardware of the bioinstrumentation device 6.

Example 11-3

As described in Example 11-1, there is a problem that a time differenceof the clock information occurs since the bioinstrumentation device andthe radiographic system are normally independent from each other and theoperation thereof is based on the individual oscillators. To cope withthe problem, in Example 11-1, the bioinstrumentation device is connectedto the clock information source apparatus 2, 4. However, when thebioinstrumentation device to be synchronized is not predetermined, thesynchronization method that the bioinstrumentation device can use cannotbe specified. A problem in this case that the reference time of timestamps to be used in the imaging system cannot be determined.

To cope with the problem, in the above-described embodiments, the systemmay be connected to a bridge device 7 that correlates differentreference times with each other as illustrated in FIG. 58 .

The bioinstrumentation device 6 and the imaging system add time stampsto images or measurement results based on the respective referencetimes.

For example, the bridge device 7 is synchronized according to the TSF,the NTP and IEEE 1588 and stores a list of combinations of therespective reference times (e.g. adds a combination of the threereference times to the list at 10 msec intervals).

Modalities send measurement results with time stamps to the bridgedevice 7, and the bridge device 7 converts the time stamps based on acertain reference time and sends them to the console.

Alternatively, modalities send measurement results to the console 14,and the console makes an inquiry to the bridge device.

With this configuration, it is possible to build an imaging system thatcan associate measurement results of two or more devices based on timeeven when the bioinstrumentation device 6 to be connected is notpredetermined.

Example 12

In the above-described embodiments, the frame rate may be changeable. Insuch cases, since the amount of dark charges in a frame image variesdepending on the frame rate, a correction table to be used for thecorrection has to be changed according to the frame rate.

It is desired that the system is configured to be able to display theframe images read by the imaging apparatus 3 on the console 14 with asshort delay as possible. This allows the user to find the abnormalposition of the subject S or the like early in the imaging period tocancel or restart the imaging process so as to reduce the exposure.

When the frame rate is variable, the imaging apparatus 3 can beconfigured to select and read a correction table in the storage 35according to the frame rate to perform the correction. However, aproblem in this configuration is that the imaging apparatus 3 takes along time for the processing, which increases the delay of displaying animage on the console 14.

To cope with the problem, in the above-described embodiments, theimaging apparatus 3 may associate information (time stamp) indicatingthe time interval between temporally adjacent frame images to each frameimage when storing the frame image.

For example, the imaging apparatus 3 stores each frame image along withthe reading start time (synchronization clock information) or thereading end time (synchronization clock information) of the frame image.

The imaging apparatus 3 does not perform the correction according to theframe rate but only adds time stamps to frame images and sends them tothe console 14.

Based on the received time stamps, the console 14 determines the timeintervals between the frame images and sequentially display the frameimages at the determined time intervals. The images thus displayed arenot corrected by image processing but has quality sufficient to make adetermination as to whether images have to be retaken again.

After displaying the images (or in parallel to displaying images whenthe CPU has sufficient processing power), the console 14 selects acorrection table according to the determined time intervals betweenframe images and performs the correction.

This configuration can minimize the amount of processing performed bythe imaging apparatus 3, and the frame images read by the imagingapparatus 3 can be displayed on the console 14 without delay. Thisallows the user to find the abnormal position of the subject S early inthe imaging period to cancel or restart the imaging process so as toreduce the exposure of the subject S.

In the above-described embodiments and examples, the clock informationsource apparatus 2, 4 is connected to both the controlling apparatus 12,2A and the console 14. However, the present invention is not limited tothis connection. For example, the clock information source apparatus 2,4 may be connected only to the radiation controlling apparatus 12, 12A,or the clock information source apparatus 2, 4 may be connected only tothe console 14.

Since the irradiating apparatus 1 is provided to emit radiation, thetiming of emitting radiation can be controlled more accurately when thecontrolling apparatus 12, 12A is directly connected to the clockinformation source apparatus 2, 4.

On the other hand, since the console 14 is provided to control theoverall imaging system 100, the console 14 can perform thesynchronization check or the like more efficiently when the console 14is directly connected to the clock information source apparatus 2, 4.

Although embodiments of the present invention have been described andillustrated in detail, the disclosed embodiments are made for purposesof illustration and example only and not limitation. The scope of thepresent invention should be interpreted by terms of the appended claims.

What is claimed is:
 1. A radiographic imaging system, comprising: anirradiation controlling apparatus that controls radiation by anirradiating apparatus; a radiographic imaging apparatus thatcommunicates in one or more synchronization methods for synchronizingwith the irradiation controlling apparatus; wherein the radiographicimaging apparatus or the irradiating apparatus selects from imagingmethods; and the irradiation controlling apparatus selects from thesynchronization methods for synchronization between the irradiationcontrolling apparatus and the radiographic imaging apparatus based onone of the imaging methods.
 2. The radiographic imaging system accordingto claim 1, further comprising: a timer; and an oscillator, and whereinthe synchronization methods include: a first synchronization method thatis less likely to be affected by decrease of accuracy of the timer or bya frequency error of the oscillator; and a second synchronization methoddifferent from the first synchronization method.
 3. The radiographicimaging system according to claim 2, wherein the irradiating apparatusand the radiographic imaging apparatus can are configured to communicatewith each other in a wireless manner and in a wired manner.
 4. Theradiographic imaging system according to claim 3, wherein the imagingmethods include: wireless still imaging in which a radiographic image isgenerated through wireless communication between the irradiatingapparatus and the radiographic imaging apparatus; and wireless serialimaging in which at least one radiographic image is generated throughwireless communication between the irradiating apparatus and theradiographic imaging apparatus, in a case in which the radiographicimaging apparatus selects the wireless still imaging, the irradiationcontrolling apparatus selects the first synchronization method, and in acase in which the radiographic imaging apparatus selects the wirelessserial imaging, the irradiation controlling apparatus selects the secondsynchronization method.
 5. The radiographic imaging system according toclaim 3, wherein the imaging methods include: wireless still imaging inwhich a radiographic image is generated through wireless communicationbetween the irradiating apparatus and the radiographic imagingapparatus; and wireless serial imaging in which at least oneradiographic image is generated through wireless communication betweenthe irradiating apparatus and the radiographic imaging apparatus, andthe irradiation controlling apparatus selects the second synchronizationmethod in a case in which the radiographic imaging apparatus selects thewireless still imaging or the wireless serial imaging.
 6. Theradiographic imaging system according to claim 3, wherein the imagingmethods include: wired serial imaging in which at least one radiographicimage is generated through wired communication between the irradiatingapparatus and the radiographic imaging apparatus; and wireless serialimaging in which at least one radiographic image is generated throughwireless communication between the irradiating apparatus and theradiographic imaging apparatus, in a case in which the radiographicimaging apparatus selects the wired serial imaging, the irradiationcontrolling apparatus selects the first synchronization method, and in acase in which the radiographic imaging apparatus selects the wirelessserial imaging, the irradiation controlling apparatus selects the secondsynchronization method.
 7. The radiographic imaging system according toclaim 3, wherein the radiographic imaging apparatus comprises aradiation detecting element, and the first synchronization methodcomprises notifying, in the wired manner, time for the radiationdetecting element to start reading a signal to the radiographic imagingapparatus from the irradiating apparatus.
 8. The radiographic imagingsystem according to claim 1, wherein the radiographic imaging apparatusselects from the imaging methods based on imaging order information. 9.The radiographic imaging system according to claim 1, wherein theradiographic imaging apparatus comprises a detecting unit that detectsconnection status of wired connection through a cable, and theradiographic imaging apparatus selects from the imaging methods based onthe connection status detected by the detecting unit.
 10. Theradiographic imaging system according to claim 9, wherein in a case inwhich the cable is connected, the radiographic imaging apparatus selectswired serial imaging in which at least one radiographic image isgenerated through wired communication between the irradiating apparatusand the radiographic imaging apparatus, and in a case in which the cableis not connected, the radiographic imaging apparatus selects wirelessserial imaging in which at least one radiographic image is generatedthrough wireless communication between the irradiating apparatus and theradiographic imaging apparatus.
 11. A radiographic imaging method for:an irradiation controlling apparatus that controls radiation by anirradiating apparatus; and a radiographic imaging apparatus thatcommunicates in one or more synchronization methods for synchronizingwith the irradiation controlling apparatus, the method comprising:selecting an imaging method; and selecting from the synchronizationmethods based on the selected imaging method; and emitting radiationfrom the irradiating apparatus as a result of the selected imagingmethod and the selected synchronization method.